Urban Flooding Risk Assessment Based on Numerical Simulation of Sub-catchment Area: A Case Study From Chengdu, China

Urbanization and climate change usually result in frequent urban flooding. Since the floods cannot be avoided, the scenario simulation combined with risk analysis is an effective way to assess the disaster level and reduce direct damage loss when facing the emergency management problems. Different from the whole city dimension, the paper proposed a sub-catchment multi-index hesitant fuzzy evaluation model for the community planning level, and takes Jinjiang District of Chengdu city as the research object. Firstly, based on the PSR (Pressure-State-Response) model, the risk assessment system has been established in three aspects, including the current situation of urban drainage, the basic geographic information, and the social influence. Secondly, A total of 14 evaluation indexes were selected, among which the pressure index came from the calculation results of ArcGIS and EPASWMM5 model such as runoff coefficient, maximum water depth, etc. Thirdly, the expert hesitate fuzzy evaluation method was used to obtain the weight of 14 indexes of each sub-catchment. Finally, the 224 evaluation results were compared, and the urban flooding disaster risk map has been drawn. It is mainly concluded that 160 medium-higher risk areas were mainly concentrated in high built-up area in study area. Furthermore, the evaluation model is very useful as a decision-making tool for mitigation of the flood hazard and its associated risk.

The 2011 Bangkok Floods: Live Peacefully (Yoo Hai Yen), Live Harmoniously (Yoo Hai Pen Suk)

<p>Thailand’s Bangkok has experienced rapid population growth and subsequent expansion over recent decades. It has resulted in an unintentional increase in vulnerability within rural-residential and metropolis areas. Flood prevention strategies, such as dams, irrigation canals, and flood detention basin, and Kaem Ling ‘Green belt Embankment’, have been slowly built and activated in response to this suburban catastrophe (Vanno). In recent years, King Rama IX of Thailand, initiated Kaem Ling’s, ‘Monkey’s Cheek’s’ project; a reference to the common parable of an intelligent monkey storing its food in its saggy cheeks rather than swallowing. This has allowed the Western and Eastern suburbs of Bangkok to function as waterways, diverting the destructive water paths away to protect the metropolis. Beginning in July 2011, a significant rainfall from the highlands of Thailand flooded down to Bangkok. With affected areas lying less than 10 metres above mean sea level and some as low as 1.5 metres, some areas remained flooded until January 2012. By October, the inundated metropolitan Bangkok began to negatively impact on industries, such as computers and automotive. Both critical supply networks for other manufacturing operations outside of Thailand. This ‘vulnerability’ where the inter-connectedness of economies could mean the closing of factories and manufacturing assembly lines in one country because of a flooding disaster in another had not been recognised. The 2011 Thailand’s flooding death tolls surpassed 815 deaths (with 3 missing), affected 13.6 million people and classed 65 of Thailand’s 77 provinces as flood disaster zones (Benfield, 2012). During the extreme environmental activity, decisions were made to close several district gates in last-ditch efforts for protecting the metropolitan areas. This caused many other peri-urban areas of Bangkok to flood. These suburban areas were intended to act as waterways to protect the metropolis, but instead became a reservoir. Nimitmai 40 Road, situated in Khlong Sam Wa district, was in the middle of the 2011 flooding zones became the locus and main area of interest in this research. Several initial studies, of precedence and technical data, explored objectives of building resilience in response to flooding and community. This research further utilised field study surveys, interviews, and case studies, all of which provided a wealth of information and contextual material. They contributed to design propositions developed through a series of critical reflections. This research aimed to build community resilience, encapsulating spiritual elements in cultural and psychosocial elements of suburban Thai community’s livelihood and to provide flood resilience through both non-technical and technical solutions. Final outcomes of the design iterations suggested a merging of Thai monastery and community centre as a spiritual anchor for the community’s resilience and strengthen my neighbourhood’s sense of place.</p>

The 2011 Bangkok Floods: Live Peacefully (Yoo Hai Yen), Live Harmoniously (Yoo Hai Pen Suk)

<p>Thailand’s Bangkok has experienced rapid population growth and subsequent expansion over recent decades. It has resulted in an unintentional increase in vulnerability within rural-residential and metropolis areas. Flood prevention strategies, such as dams, irrigation canals, and flood detention basin, and Kaem Ling ‘Green belt Embankment’, have been slowly built and activated in response to this suburban catastrophe (Vanno). In recent years, King Rama IX of Thailand, initiated Kaem Ling’s, ‘Monkey’s Cheek’s’ project; a reference to the common parable of an intelligent monkey storing its food in its saggy cheeks rather than swallowing. This has allowed the Western and Eastern suburbs of Bangkok to function as waterways, diverting the destructive water paths away to protect the metropolis. Beginning in July 2011, a significant rainfall from the highlands of Thailand flooded down to Bangkok. With affected areas lying less than 10 metres above mean sea level and some as low as 1.5 metres, some areas remained flooded until January 2012. By October, the inundated metropolitan Bangkok began to negatively impact on industries, such as computers and automotive. Both critical supply networks for other manufacturing operations outside of Thailand. This ‘vulnerability’ where the inter-connectedness of economies could mean the closing of factories and manufacturing assembly lines in one country because of a flooding disaster in another had not been recognised. The 2011 Thailand’s flooding death tolls surpassed 815 deaths (with 3 missing), affected 13.6 million people and classed 65 of Thailand’s 77 provinces as flood disaster zones (Benfield, 2012). During the extreme environmental activity, decisions were made to close several district gates in last-ditch efforts for protecting the metropolitan areas. This caused many other peri-urban areas of Bangkok to flood. These suburban areas were intended to act as waterways to protect the metropolis, but instead became a reservoir. Nimitmai 40 Road, situated in Khlong Sam Wa district, was in the middle of the 2011 flooding zones became the locus and main area of interest in this research. Several initial studies, of precedence and technical data, explored objectives of building resilience in response to flooding and community. This research further utilised field study surveys, interviews, and case studies, all of which provided a wealth of information and contextual material. They contributed to design propositions developed through a series of critical reflections. This research aimed to build community resilience, encapsulating spiritual elements in cultural and psychosocial elements of suburban Thai community’s livelihood and to provide flood resilience through both non-technical and technical solutions. Final outcomes of the design iterations suggested a merging of Thai monastery and community centre as a spiritual anchor for the community’s resilience and strengthen my neighbourhood’s sense of place.</p>

A Conceptual Design of Smart Management System for Flooding Disaster

Disasters pose a real threat to the lives and property of citizens; therefore, it is necessary to reduce their impact to the minimum possible. In order to achieve this goal, a framework for enhancing the current disaster management system was proposed, called the smart disaster management system. The smart aspect of this system is due to the application of the principles of information and communication technology, especially the Internet of Things. All participants and activities of the proposed system were clarified by preparing a conceptual design by using The Unified Modeling Language diagrams. This effort was made to overcome the lack of citizens’ readiness towards the use of information and communication technology as well as increase their readiness towards disasters. This study aims to develop conceptual design that can facilitate in development of smart management system for flooding disaster. This will assist in the design process of the Internet of Things systems in this regard.

HOME GARDEN VALUE IN ISLAMIC PERSPECTIVE FOR RURAL DEVELOPMENT IN SITU UDIK BOGOR

The objective of this research was to investigate home garden value for rural development in Situ Udik Bogor West Java. The research method used ethnographic qualitative approach. This method was related to community, social and environment. The data were collected through in-depth interviews, observation, and documentation. The selection of sample as informant exert purposive sampling technique. The result was probed meticulously through triangulation technique. The result showed that chief of village play imperative role to flourish rural community for program namely one banana trees in each home garden of society. The other was the home gardening impact on economic value. Society in the village can gain numerous merits of one banana trees which is cultivated in yard including community can exert outcome of banana yield for paying property taxes, add household income and allocate for school fee children. The other is to release ecology value. Home gardening has some function including protecting water from the surface flow and avoids environment from flooding disaster, reducing emission which is caused by global warming or climate change, produce oxygen and safeguard of soil fertility. Islam pledge to the person who conserves the natural environment like cultivating trees refers to produce alms and worship.

Weather systems and extreme rainfall generation in the 2019 north Queensland floods compared with historical north Queensland record floods

Earlier papers have addressed floods from warm-air advection (WAA) in southeast Australia and around the globe, and extreme rainfall in US hurricanes and Australian tropical cyclones (TCs). This is the first paper to address the WAA phenomena in causing monsoon and TC floods and in TC-like systems which develop over the interior of northern Australia. The inland events help explain Australia’s worst tropical flooding disaster in 1916. A disastrous series of floods during late January and early February 2019 caused widespread damage in tropical north Queensland both in inland regions and along the coast. This occurred when some large-scale climate influences, including the sea surface temperatures suggested conditions would not lead to major flooding. Therefore, it is important to focus on the weather systems to understand the processes that resulted in the extreme rainfall responsible for the flooding. The structure of weather systems in most areas involved a pattern in which the winds turned in an anticyclonic sense as they ascended from the low to middle levels of the atmosphere (often referred to as WAA) which was maintained over large areas for 11 days. HYSPLIT air parcel trajectory observations were employed to confirm these ascent analyses. Examination of a period during which the heaviest rain was reported and compared with climatology showed a much stronger monsoon circulation, widespread WAA through tropical Queensland where normally its descending equivalent of cold-air advection is found, and higher mean sea level pressures along the south Queensland coast. The monsoon low was located between strong deep monsoon westerlies to the north and strong deep easterlies to the south which ensured its slow movement. This non-TC event produced heavy inland rainfall. Extreme inland rainfall is rare in this region. Dare et al. (2012), using data from 1969/70 to 2009/10, showed that over north Queensland non-TC events produced a large percentage of the total rainfall. The vertical structure associated with one of the earlier events that occurred in 2008 had sufficient data to detect strong and widespread WAA overlying an onshore moist tropical airstream. This appears to have played a crucial role in such extreme rainfall extending well inland and perhaps gives insight to the cause of a 1916 flooding disaster at Clermont which claimed around 70 lives. Several other events over the inland Tropics with strong WAA also help explain the 1916 disaster.

Keeping Feet Dry: Rotterdam’s Experience in Flood Risk and Resilience Building

Rotterdam City in the South of Holland is one of the most vibrant cities you will find in the Netherlands. The city has gone through a transformation from the time it was bombed in the 1940s up to the time that a part of the city was flooded in 1953. Through extensive rebuilding and the Delta Plan project, the city has been well protected against any flooding disaster that may come. However, how resilient really is Rotterdam? Through in-depth interviews of key stakeholders in the City of Rotterdam, the study investigates the collective engagement in the city and how this has helped shape Rotterdam’s position in urban resilience. The study used the Collective Engagement Urban Resilience Framework as a framework to understand how disaster prone cities transform itself to become disaster resilient.

MONITORING TEMPORAL AND SPATIAL CHANGES OF LAND USE AND LAND COVER BASED ON REMOTE SENSING IN THE HILLY REGION OF CENTRAL SICHUAN BETWEEN 1989 AND 2009

In recent years, under the background of government policy and the development of social economy, land use in hilly region of central Sichuan has changed drastically. Especially the Changzhi soil erosion control project that has been carried out since 1989 and the policy of converting from farm land to forest which has been carried out after flooding disaster in 1998, have seriously affected the land use in hilly region of central Sichuan between 1989 and 2009. In order to detect these changes and acquire the land use information, this study was conducted in Lizixi basin which is the typical area in hilly region of central Sichuan. Supervised classification was applied to the processing procedure of TM, SPOT data in 1989, 1999 and Rapideye data in 2009. The results were further improved by visual interpretation. The overall classification accuracy reaches 88.33% and the kappa is 0.8350. The elevation was classified into five grades to detect the land use distribution in different elevation gradients in 2009. Post-classification comparisons of the classified images indicated that the major change consists that the cultivated land is decreasing and forest is increasing. The force factor of these changes may be the policy of converting from farmland to forest. Because of the labor shortage, 53.29% of the decreased cultivated land has changed to abandoned arable land which is covered by lush grass and mainly distribute on the halfway up to the hill. The urban area has enlarged 7 times due to the large number of migrants from rural to urban. Overall these changes reflect the regional policies and human activities are the major and important force factors of changes in the hilly region of central Sichuan during last two decades.