Posts Tagged ‘Coastal’

Methodology for Assessment of Natural Hazard Vulnerability in U.s. Coastal Zone Using Remote Sensing

Friday, November 13th, 2009

INTRODUCTION

Coastal is defined as “the coastal waters (including the lands therein and thereunder) and the adjacent (including the waters therein and thereunder), strongly influenced by each other and in proximity to the shorelines of the several coastal states, and includes islands, transitional and intertidal areas, , wetlands, and beaches.” were some of the first settled in the country, and have always accounted for a major percentage of the overall population. They were the primary centers for transportation, tourism, recreation, commercial fishing, and other industry. This coastal remains a crucial segment of the nation’s overall economy. A variety of hazards regularly threaten this coastal . Severe such as hurricanes, tropical cyclones, and nor’easters are particularly harsh on coastal areas, often resulting in damages from high winds, storm surge, flooding, and shoreline erosion. Tsunamis, whose is characterized by potentially devastating flood inundation, are uniquely coastal events resulting from , landslides, or volcanic activity. are also subjected to the impacts of long-term hazards such as , potential sea-level rise, and global climate change.

Coastal can significantly affect or even alter the environment. Their impacts are generally not considered to be “disastrous” unless they involve damages to human populations and infrastructure. When people and property are not present, hazards are merely processes that alter the environment. When people and property is present then the impacts of hazards are viewed quite differently. The primary focus is no longer on the processes associated with a major hazard event, but instead on the disastrous results that can be measured by lives lost, , and economic and environmental impacts.

The impacts of hazards are becoming increasingly costly and devastating. Hazard impacts on the environment become more devastating because human development has altered the ability of systems to recover from such events. Experts believe that the statistics on disaster losses continue to rise worldwide due to a combination of factors that include a rise in the number of due to global climate change or cyclical trends, and an increase in human exposure in hazardous locations.

Some of the decrease in disaster damages worldwide could also be the result of improvements in disaster monitoring and reporting capabilities, particularly in developing countries. But disaster loss increases in the United States seem to be most closely tied to increased human exposure in high risk areas such as the nation’s coasts.

The United States has an expansive and diverse coastline that supports a disproportionate percentage of the nation’s population. The nation’s 451 coastal counties contain just over 50 percent of the U.S. population, yet only account for about 20 percent of the total U.S. land area. During the last decade, 17 of the 20 fastest growing counties were located along the coast. In addition, 19 of the 20 most densely populated counties in the nation are coastal counties. These coastal counties possess economic gain through resources, maritime trade and commerce. These coastal counties also possess economic loss due to the hazards, overexploitation and exponential population growth. An of both the economic gain and economic loss is briefly discussed as follows.

Economic gain in U.S. coastal

Nature article (May 1997), a group of ecologists estimated the value on ecosystem in the coastal . They estimated that the worth of the services for marine ecosystems is approximately $21 trillion per year. According to Sea Technology magazine, the value of goods and services sold by the ocean/marine industry was estimated in 1995 as $60 billion annually. Offshore oil and gas production has become very important and the 1996 value was more than $8 billion and the annual offshore production is increasing. According to the National Oceanic and Atmospheric Administration (NOAA), 77 million pounds (meat weight) of shellfish were harvested from U.S. coastal waters in 1995, with a dockside value of $200 million.

Current NOAA estimates concerning the recreational uses of U.S. coastal areas includes: approximately 94 million people boat and fish annually; the average American spends 10 recreational days on the coast each year; The coasts (excluding the Great Lakes coastline) support 25,500 recreational facilities; More than 180 million Americans visited ocean and bay beaches in 1993; Recreational fishing contributes $13.5 billion annually to the U.S.

economy; Coastal recreation and tourism generate $8 to $12 billion annually.

Economic loss in U.S. coastal

Disaster losses in the United States coastal are currently estimated conservatively at $50 billion annually. The disaster loss between 1975 and 1994 is estimated as $500 billion. 80 percent of the losses were imposed by and 10 percent were the result of earthquakes and volcanoes. A great earthquake (magnitude 8 or larger) has not struck a major metropolitan area since the 1906 San Francisco earthquake. An extreme or catastrophic hurricane (Class 4 or 5) has not directly struck a major urban area since the one that hit Miami, Florida, in 1926. Yet even without such disasters, which might create losses well over $100 billion, the overall costs of hazards, such as extreme weather, drought, and wildfires, are estimated at $54 billion per year for the past 5 years, or approximately $1 billion per week. In the United States, the direct costs to repair the damage average about $20 billion per year, of which over $15 billion is due to tornadoes, hurricanes, floods and earthquakes.

The FEMA coastal erosion study conducted by The Heinz Center for Science, Economics and the Environment estimates that approximately 25 percent of homes and other structures within 500 feet of the U.S. coastline and the shorelines of the Great Lakes will fall victim to the effects of erosion within the next 60 years. Especially hard hit will be areas along the Atlantic and Gulf of Mexico coastlines, which are expected to account for 60 percent of nationwide losses. The report estimates that costs to U.S. homeowners will average more than a half billion dollars per year, and that additional development in high erosion areas will lead to higher losses. Thirty-four floods have been reported in Wake County (data source: NDCD and SHELDUS). The total coastline of mapped shoreline of Gulf of Mexico coast is about 8058 km out of which 3387 kms is in very high risk, 1056 kms is in high risk, 2968 km is in moderately risk and 547 kms is in low risk category due to . So the 42 % of the coast line is in high risk, 37 % moderate risk and 8 % low risk (Robert Thieler et.al. 2001).

Hurricane Mitch, one of the most powerful and damaging storms experienced in Central America, struck between 26 October and 1 November 1998. A Category V hurricane, the event was characterized by intensive rainfall and high winds, dumping a year’s worth of precipitation in less than one week on the region, causing the overflow of rivers, floods, mudslides and landslides. Thousands of people were killed and left homeless. Mitch caused billions of dollars of damage, and left huge tasks of reconstruction, resulting in the loss of decades of development efforts in the region.

The Economic Commission for Latin America and the Caribbean (ECLAC) estimates that the direct cost of replacing the lost and damaged infrastructure in the region after Hurricane Mitch is some US$5,000 million (Caballeros, 1999).

Recent large-scale disasters such as Hurricane Mitch and Georges, and the earthquake in Armenia, Colombia have demonstrated the of society. It is widely recognized that recent population growth, rapid urbanization and the socioeconomic structure in Central America have increased of these countries to hazards.

These disasters faced by the inhabitants both by and anthropological effects lead to the formation of legislation / laws to govern.

Legislation & major acts in U.S. Coastal

The economic loss and economic yield as such felt by the inhabitants of the Earth has resulted in the formation of legislation. This legislation is framed for the sustainable use of the available resources. When the loss is severe or the gain is enormous; the laws needs some revision hence they were amended periodically. Some of the Laws and Acts pertaining to U.S. coastal were National Environmental Policy Act, Clean water Act, Marine Protection, Research and Sanctuaries Act, Ocean Dumping Act of 1972, Water Resources Development Act of 1996, Coastal Management Act of 1972, Marine Mammal Protection Act of 1972, Magnuson-Stevens Fishery Conservation and Management Act of 1976 Endangered Species Act 1973, Nation wise Invasive Species Act of 1996, Oil Pollution Act of 1990, Comprehensive environmental response, compensation, and liability act of 1980, Rivers and Harbor Act of 1899, The Submerged Lands Act of 1953, The Fish and Wildlife Coordination Act of 1934, Land and Water Conservation Fund Act of 1965, Outer Continental Shelf Lands Act, Resource Conservation and Recovery Act of 1976 and The Coastal Barriers Resources Act of 1982.

Hence in order to amend these laws the integration in different fields is attempted and discussed as follows.

RESULTS AND DISCUSSION

of Hazard

hazard is a phenomenon which occurs in proximity and poses a threat to people, structures or economic assets and may cause disaster. They are caused by meteorological, biological, geological, seismic, hydrological, or conditions or processes in the environment. Hazard is the process of estimating, for defined areas, the probabilities of the occurrence of potentially – damaging phenomenon of given magnitudes within a specified period of time. Hazard involves analysis of formal and informal historical records, and skilled interpretation of existing meteorological, topographical, geological, geomorphologic, hydrological, and land-use maps.

Office of United Nations Development Relief Organization (UNDRO), defines the term as: “The degree of loss to a given element or set of elements at risk resulting from the occurrence of a phenomenon of a given magnitude. It is expressed on a scale from 0 (no damage) to 1 (total damage)”. The of an element is usually expressed as a percentage loss (or as a value between 0 and 1) for a given hazard severity level. The measure of loss used depends on the element at risk, and accordingly may be measured as a ratio of the numbers of persons killed or injured to the total population, as a repair cost or as the degree of physical damage defined on an appropriate scale. In a large number of elements, like building stock, it may be defined in terms of the proportion of buildings experiencing some particular level of damage.

is an interdisciplinary process under-taken in phases and involving on-the-spot surveys and the collation, evaluation and interpretation of information from various sources concerning both direct and indirect losses, short- and long-term effects. It involves determining not only what has happened and what assistance might be needed, but also defining objectives and how relevant assistance can actually be provided to the victims. It requires attention to both short-term needs and long-term implications.

The United States is becoming more vulnerable to hazards mostly because of changes in population and national wealth density. Due to this, people and infrastructure have become concentrated in disaster-prone areas. Hazards threaten the sustainable development of United States, destroying years of development efforts and investments, placing new demands on society for reconstruction and rehabilitation, and shifting development priorities away from long-term goals while immediate needs are met. For most of the 20th century, the United States has largely spared the expense for catastrophic disaster. Significant progress has been made in understanding the various impacts that hazards produce on human and environments. Numerous research activities have been undertaken following the major of the past few years. Unfortunately, much of this research is piecemeal and has not been incorporated into any type of comprehensive database on disaster losses.

hazards such as hurricanes and earthquakes do not have to become disasters. With proper planning, including proper environment management, much of the risk can be reduced. The risks posed by hazards in United States are exacerbated by social and environmental trends such as rapid urbanization and unplanned human settlements, poorly engineered construction, lack of adequate infrastructure, poverty, and inadequate environmental practices such as deforestation and land degradation.

Given the significant costs of the nation’s catastrophic disasters, focus has shifted in recent years to expand beyond emergency preparedness and response to include a more long-term emphasis on disaster loss reduction. Hence it requires for a quantitative of hazards for coastal . This quantitative of hazards is aimed to minimize either an individual’s or a community’s to future disaster damages. Over the years, progress has been made in reducing hazard impacts through better predictions, forecasts, and warnings, particularly for meteorological hazards such as coastal storms and floods. General improvements in hurricane and tsunami prediction, and river and lake level forecasting, have been possible the latest in computer modeling technology. NOAA’s National Weather Service (NWS) is currently working with several new technological systems that are intended to significantly improve future flood forecasting capabilities. Though there were lot of techniques available to assess due to hazard quantitatively still it is necessary to acknowledge the scientific and technological information needs throughout the various hazards-related disciplines and integration. Although significant progress has been made in the research and science associated with hazards during the past 20 years, and improvements in technology and understanding about hazards and how to access its quantitatively requires a real-time networked scientific database.

Universities and research institutions (particularly the National Science Foundation), along with government agencies such as NOAA and USGS that maintain scientific hazards-related responsibilities, have contributed to advances in the scientific study of hazards. There is now more quantitative information available about the origins and behavior of but the concept of integration of the available data sets is lagged.

This study is to integrate all the fields acting in coastal for the of . Maps delineating hazard-prone areas at national, state, and local levels are needed to provide more comprehensive hazards information on a variety of phenomena, including coastal storms, floods, tsunamis, hurricanes, typhoons, landslides, wildfires, drought, earthquakes, etc. Much of this information already exists, but issues such as data integration, compatibility, scales, accuracy, and resolution need to be addressed to make the information useful at the local level. Better methodologies and models are also needed for conducting hazard assessments that can incorporate highly variable local conditions and characteristics. This calls for the site specific models for better estimates.

Computer-based geographic information systems could be used to analyze hazards information and provide national risk data to state and local governments in quick and easy manner. Specific models could be generated by the GIS software. New high-resolution sensing capabilities could be examined for use in large-scale risk and . Hence, Sensing and GIS is to be intergrated and modeled for the of quantitative hazard .

Improvements in monitoring, data collection, and data processing account for most of the advancements made in short-term weather-related forecasting. Better modeling capabilities, along with a more thorough understanding of variables, such as global climate change and sea-level rise, are needed to improve long-range forecasting and planning for coastal hazard impacts.

GIS integration / modeling for hazard

GIS is one of the powerful tools which can be used for the of Hazards (NHV). Due to these techniques, hazard mapping and could be performed for the coastal . These maps will help the authorities for quick of potential impact of a hazard and initiation of appropriate measures for reducing the impact. This data will help the planners and decision-makers to take positive steps in time.

GIS applications in the coastal are diversified and case-based. Applications studies such as (a) coastal mapping, (b) environmental monitoring, (c) coastal process modelling, (d) navigation and port facilities management, (e) coastal environmental / hazard , (f) coastal management / strategic planning, and (g) coastal ecological modeling could be done through GIS.

Coastal Mapping is mainly focused on thematic mapping in the coastal , such as mapping chlorophyll concentration TM data (Chen et al. 1996). Environmental monitoring is one of the routine tasks in CZM, which include monitoring water quality and habitat/biodiversity, and beach watch. Coastal processes modeling of physical environment change in the coastal includes the simulation of effects of sea-level rise (Ruth and Pieper 1994, Grossman and Eberhardt 1992, Zeng and Cowell 1998, 1999, Hennecke 2000), the of human intervention of shoreline change (Huang et al. 1999), the use of historical data to predict future coastline change (Sims et al. 1995) and the study of beach morphodynamics (Humphries and Ligdas, 1997). There are another two subcategories of the applications of hazards, namely, short-term and long-term tasks. The former is exemplified with monitoring and predicting oil spill (Belore, 1990), while the latter is demonstrated by coastal hazard / due to climate change (Lee et al. 1992, Sims, et al., 1995; Deniels et al. 1996, Hickey et al. 1997, Zeng and Cowell 1999, Hennecke et al. 2000, Esnard et al. 2001). Coastal management / strategic planning involve assessing sustainability of the environment, social and economic viability. The above said studies carried out in coastal are to be integrated sensing and GIS for analysis.

The categories of GIS applications in coastal could be broadly categorized into three levels.

a) Level 1: as data management and mapping tools,

b) Level 2: as basic data analysis (query) and mapping tools, and

c) Level 3: as decision-supporting tools (modelling / simulation).

Most current implementations of Coastal GIS are still at Level 1 and Level 2. It is expected that Level 3 implementations will rapidly increase in the near future as the continuing improvement in GIS functions and more user-friendly interface become available in the market. Hence for the study of Quantitative of Hazard Level 3 application is to be adopted.

The two basic approach / analysis, which should be followed for geospatial database development were given below.

Integrated approach:

a) integration of different level of application,

b) integration of vector and raster (data and functions),

c) integration of knowledge of different expertise, and

d) integration of different scales in time and space.

Because of the nature of integration, GIS applications should consider long-term integration. This includes the vertical integration that involves different application (and potential) levels, and horizontal integration that involves other interest groups. Therefore, issues must be addressed from database design, data sharing to tool-making (analysis functions) and experience sharing.

Multi-criteria analysis

a) multi – factors controls

Since coastal system has a complex hierarchical structure with multi-forcing exerting on each of subsystem, no mater which aspect of the system to be investigated, multi-variable analysis is an essential methods in the coastal environment.

b) multi – discipline approach for decision Other than the multi-factors, there are multiple interest groups of coastal community, therefore, good solutions to any coastal issues can only be derived from multidiscipline approach.

Output of the analysis

I. Historical and real-time information with respect to hazards will be gathered by satellite sensing, aerial photographs and by other conventional means and integrated with GIS RDBMS. This results in an extensive geo- database.

II. Through the modeling technique and by the GIS RDBMS we can evaluate the likelihood of experiencing specific hazard in the future, and an estimation of intensity and probable level of impact.

Each hazard will be evaluated for three characteristics:

1. Likelihood of Occurrence, i.e., expected frequency;

2. Likely Range of Impact, i.e., predictable size and location of impact; and

3. Probable Level of Impact, i.e., estimated strength and damage potential.

III. The level of severity of hazards will be quantified in terms of the magnitude of the occurrence as a whole (event parameter) or in terms of the effect the occurrence would have at a particular location (site parameter).

IV. For quantitative hazard , some weight value has to be added to the attribute column (slope, subsurface geology, current action, wave action, meterology, wind action etc). The values that will be given in the attribute columns could be calculated with the help of the equation 1 modeled in GIS environment.

hazard = (Wgeology + Wslope + Wwind + Wmeteo + Wsiesmisivity

+ Wgeomorphology + Wetc…) (1)

Based on the above formula, hazard values could be retrieved by clicking on any land parcels from the coastal map. Such kind of values will have no meanings for the end users. To make the result more acceptable, a separate domain is to be created in which the resultant values will be divided into three classes: very high, high, moderate and low hazard areas

Weights Class:

Values below than 30 Low hazard Area

Values between 30-40 Moderate Hazard Area

Values between 40-50 High Hazard Area

Values between 50-60 Very High Hazard Area

V. Hazard mitigation plan is to be developed and it will possess these five steps –

• identification of hazards that could impact the community,

of the community’s to hazards,

of the community’s capability to respond to a disaster,

of the community’s current policies and ordinances that affect hazard mitigation, and

• development of hazard mitigation strategies that can be implemented to reduce future .

VI. By all the above factors site specific models for the of hazard could be generated GIS for U.S. coastal . This will serve as an input for further amendment of legislation concerned with U.S coastal .

CONCLUSION

U.S. coastal counties possess economic gain through resources, maritime trade and commerce and economic loss through hazards, overexploitation and exponential population growth. About 80 percent of the losses were by and 10 percent were by earthquakes and volcanoes. Hence in order to minimize the loss due to hazard a computer based geospatial database is adopted for hazards information retrieval and to provide national risk data to the state and local governments. Site specific models were proposed for U.S. coastal by integrating GIS software and high-resolution sensing to quantify the large-scale risk and . This modeling study could also be applied to developing countries such as India, Pakistan, Srilanka etc. for the hazard in their coastal zones.

The Author is a Project Manager in Stesalit Inc.
http://www.stesalit-inc.com/userexperience.html

307 | posted at November 13th, 2009 in natural | Tags: , , , , , , , , , , , , , , , , , , , , , , , , , , , , , ,

Powered by Yahoo! Answers