Wednesday, March 18, 2020

Global Biodiversity Data and Information Essay Example

Global Biodiversity Data and Information Essay Example Global Biodiversity Data and Information Essay Global Biodiversity Data and Information Essay 1964). Other datasets available under this category are presented in the Tables 1 and 2. Table 1 List of selected global biodiversity data Data Major world ecosystem (Olson et al. 1983) Global eco-regions (Bailey, 1989) Global biodiversity â€Å"hot spots† Mathews vegetation, cultivation intensity and albedo Mathews global vegetation, land use and seasonal albedo World vegetation cover (Fedorova et al. , 1994) Global primary productivity:phytomass, NPP, and mortmass (Bazilevich, 1994) World wilderness areas Natural wetlands (Mathews and Fung) World vegetation map (Murai and Honda, 1987) FAO-UNESCO soil map of the world Frontier forests of he world Status of the worlds coral reefs Monthly global vegetation index Forest resources of the world Global assessment of human induced soil degradation World terrestrial biomes (Cox and Moore, 1993) BSL = Blackwell Scientific, London GRID= Global Resource Information Database FAO = Food and Agriculture Organization UNEP = United Nations Environm ent Programme WRI = World Resources Institute Format Digital raster Digital vector N/a Digital raster Digital raster Digital raster Digital raster Digital vector Digital raster Digital raster Digital vector N/a 100 x 100 Digital raster Tabular data Digital vector paper Spatial resoluton 0. 0 x 0. 50 0. 30 x 0. 30 N/a 10 x 10 10 x 10 100 x 100 100 x 100 1:2 M 10 x 10 12. 7kmx12. 7km 1:5 M N/a 4 km x 4 km 100 x 100 1:10 M Source GRID-Geneva GRID-Geneva CI NGDC NGDC NGDC NGDC UNEP GRID-Geneva GRID-Geneva FAO WRI WRI NGDC FAO ISIRC BSL CI = Conservation International NGDC = National Geophysical Data Center WCMC = World Conservation Monitoring Center ISIRC= International Soil Reference and Information Centre 5 Table 2. Data available for Marine Resources Data Data Source Coastline data World Resources Institute Marine fisheries data FAO Coral reefs data WCMC, UNEP, and IUCN Inshore marine fishes data International Centre for Living Aquatic Resources Management (ICLARM), FAO and IUCN Seagrasses Incompletely collated Mangrove Available from various sources Marine Turtles Available from various sources Paine (1997) prepared a world ranking of mega-biodiversity countries (see Table 3). These countries have been ranked according to the species richness of mammals, birds and flowering plants of all the countries of the world. Table 3. World ranking of mega-biodiversity countries (Paine,1997) Country Mammals Mexico 450 Indonesia 436 Zaire 415 Brazil 394 China 394 Colombia 359 Peru 344 India 316 Venezuela 305 Ecuador 302 Cameroon 297 Malaysia 286 Australia 252 South Africa 247 Panama 218 Papua New Guinea 214 Vietnam 213 Costa Rica 205 Philippines 153 Madagascar 105 Birds 1,026 1,531 1,096 1,635 1,244 1,695 1,678 1,219 1,296 1,559 874 736 751 790 926 708 761 850 556 253 Flowering Plants 25,000 27,500 11,000 55,000 30,000 50,000 17,121 15,000 20,000 18,250 8,000 15,000 15,000 23,000 9,000 10,000 7,000 11,000 8,000 9,000 4. Conservation areas data There are currently about 30,350 protected areas in the world covering more than 13. 23 million square kilometers i. e. about 8. 83% of the land on Earth (Green and Paine, 1997). Of these, 2,149 protected areas (2. 5 million square kilometers) are known to have at least some marine element, of which 824 are island-protected areas. A comprehensive list of 6 these prot ected areas can be found in â€Å"the 1997 United Nations List of National Parks and Protected Areas† (IUCN, 1998). The UN list provides information on the protected areas of the world which are greater than 1,000 ha. nd falling under one of the IUCN categories. The IUCN classification designed for cross-country comparisons omits some significant sites such as areas less than 1,000 ha. , hunting reserves, and areas managed by private organizations. The World Conservation Monitoring Centre (WCMC) maintains a larger database of protected areas that includes forestry reserves, private nature reserves and other protected areas and indigenous reserves in addition to IUCN defined protected areas. Both UN list and protected areas database can be accessed through the WCMC database at www. wcmc. org. The Man and Biosphere program (MAB) is guided by the MAB International Cocoordinating Council consisting of 34 Member States elected by the UNESCO General Conference. Programme activities are conducted in more than 100 countries under the direction of MAB National Committees or focal points. As of December 1999, there are about 357 MAB reserves worldwide. Biosphere reserves are alternative types of protected areas designed primarily for â€Å"in situ† conservation of natural and semi- natural areas, sustainable management of natural resources for local people, scientific research and monitoring, and environmental education and training. The MAB Programme is an interdisciplinary programme of research and training intended to develop the rational use and conservation of the resources of the biosphere, and to improve global relationship between people and the environment. A detailed list of the Man and Biosphere Reserves can be found at the UNESCO Biosphere Reserve Directory at unesco. org/mab/bios1-2. htm. UNESCO also operates a COastal and MARine programme (COMAR) for marine environment. There are about 1,011 Ramsar wetlands covering an area of over 71. million hectares. These areas as designated following The Convention on Wetlands, signed in Ramsar, Iran, in 1971. The Conventions mission is â€Å"the conservation and wise use of wetlands by national action and international cooperation as a means to achieving sustainable development throughout the world†. Detailed information on the Ramsar sites can be found at www. ramsar. org. Currently, there are about 582 â€Å"World Heritage Sites† of which 445 are cultural, 117 are natural, and 20 are of mixed types. These areas are classified as â€Å"outstanding universal value† with the principal aim of fostering international cooperation in safeguarding these important sites. World Heritage lists are established following the convention concerning the protection of the world cultural and natural heritage in Paris in 1972. Detailed information of these sites are available at UNESCO’s official website www. unesco. org/whc/heritage. htm. 4. 3 Species data Species information is considered as the basic unit of documenting and describing biological diversity. This is supported by sound theoretical as well as operational reasons (Stanton and Lattin, 1989). Microbiologists, however, are in disagreement with this approach who highlighted the importance of having a different approach in defining 7 biodiversity. Serious attempts are in place to us e alternative basis for measuring biological diversity. It is extremely difficult to inventory all the species on Earth. This is the reason why the exact number of species on Earth is unknown. A conservative estimate ranges from 3 to 100 million species. For practical purposes, a total of 12. million species has been estimated as the known species. Out of this, only 1. 7 million species have been described. (see Table 4). This figure suggests that only 13% of species on Earth have yet been described. Furthermore, comprehensive catalogues of all 1. 7 million species are not available and are poorly known in biological terms. Table 4. Known and estimated total number of species on Earth (WCMC, 1992). G roups Known Estimated total % number of number of known species species species 950,000 8,000,000 11. 9 70,000 1,000,000 7. 0 75,000 750,000 10. 15,000 500,000 3. 0 5,000 500,000 1. 0 4,000 400,000 1. 0 250,000 300,000 83. 3 40,000 200,000 10. 0 40,000 200,000 10. 0 70,000 200,000 35. 0 40,000 150,000 26. 7 45,000 50,000 90. 0 1,700,000 12,500,000 13. 6 Insects Fungi Arachnids Nematodes Viruses Bacteria Plants Protozoans Algae Molluscs Crustaceans Vertebrates World Total The available information, in some cases, is inaccurate and biased. Inaccurate because it contains errors of taxonomic judgment and biased because a detailed and relatively accurate information is available only for some groups. As shown in the Table 4, description of species has dominated by the world of animals and plants, frequently ignoring fungi and micro-organisms. Viruses, bacteria, fungi, insects, algae and nematodes are among the least described species (Table 5. ). 8 Table 5. Approximate number of described species, number of estimated species and working figure (in thousands) of least described species group (UNEP, 1995) Species Described species 4 4 72 40 270 25 950 1,362 Number species low of estimated Working figure high 1,000 400 3,000 1,000 2,700 1,500 1,000 400 500 320 1,000 400 100,000 8,000 109,200 12,020 Viruses Bacteria Fungi Algae Plants Nematodes Insects Total 50 50 200 150 300 100 2,000 2,850 Continental distribution of these described species (global total) shows that Africa, Asia and the Pacific, and Latin America has the highest biodiversity. Moist tropical forests cover approximately 8% of the world’s land surface but holds more than 90% of the world’s species. The information on species richness would consist of a complete catalogue of all the species occurring in the country or area under consideration. In practice, this is extremely difficult to achieve. Species composition changes through time and majority of the species are very small and are difficult to identify and count in situ. Moreover, collecting and counting all micro-organisms even for a small area is extremely difficult. For this reason, country species diversity data are predominantly available for mammals, birds, reptiles, amphibians, freshwater fishes, flowering plants, conifers and cycads, ferns and higher plants. In practice, overall species counts tend to be used for terrestrial vertebrates (mammals, birds, reptiles, amphibians), for some group of fishes and for few well-known invertebrate groups such as butterflies and dragonflies. Under such circumstances, information on endemism, which refers to a species confined entirely to that area or country, is important in relation to its importance in a wider context Out of 250,000 flowering plant species, around 200 have been domesticated as food plants of which 25-30 are a crop of major world importance, judged largely by global production and economic criteria. FAO 1984 data suggest that there are more than 100 species that are significant at the national level. However, this database does not cover crops from home-gardens and data from many countries are missing. A list of data and information on species available from various sources are presented in the Table 6. 9 Table 6. A List of available data and information on Species 1. 2. 3. Known numbers of invasive and native species in various countries/areas The percentage of threatened terrestrial vertebrate species affected by introductions in the continental landmasses of the different biogeographic realms and on the worlds islands. Countries species diversity (mammals, birds, reptiles, amphibians, freshwater fishes, flowering plants, conifers and cycads, ferns and higher plants) including total species, endemic species, and breeding species IUCN red list of Threatened species including endangered, vulnerable, rare, indeterminate and insufficiently known for mammals, birds, reptiles, amphibians, fishes, invertibates and plants The numbers of new species of organisms described as new to science in 1992 compared with the number of authors involved and the number of known and stimated species National red data books Major food crops with family/species, production, origin of species, major germplasm collections, no. of species in genus, species status, distribution of genus, other species in genus used and conservation notes Domestic livestock Approximate number of described species currently recognized together with number of estimated species (low and high) and working figure with accuracy The number of species o f flowering plants recorded in floras of areas of different sized from all parts of the world. Number of recorded species extinctions since 1600 Estimates of the number of described species and possible undescribed species of microorganisms Major groups of organisms: described species as proportions of the global total Major groups of organisms: possibly-existing species as proportions of the global total Regions of high bryophyte diversity Selected orders and families of mosses Selected orders and families of liverworts (including hornworts) Lichen diversity by specific region Orders and families of larger green algae Orders and families of brown algae Orders and families of red algae Diversity of marine algal (Seaweed) floras Stonewort diversity Distribution of higher plants by continents Species richness and endemism: higher plants (flowering plants, gymnosperms, ferns, number of endemics, %endemism) 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. CITES, the Convention on International Trade in Endangered Species of Wild Fauna and Flora, ma intains a data base of the most endangered species (Appendix I) and other species at risk (Appendix II and Appendix III). Appendix I include all species threatened with extinction, which are or may be affected by trade. Appendix II includes all species that are not necessarily threatened with extinction but may become extinct in the future and other species, which are similar to these species. Appendix III includes all species that any party identifies as being subject to regulation within its jurisdiction for the purpose of preventing or restricting exploitation. The following table provides an update of number of species on the CITES Appendices 10 Table 7. Number of Species on the CITES Appendices Appendix I Species Sub species Populns Appendix II Species Sub species Populns Appendix III Species Sub species Populns Mammals Birds Reptiles Amphibians Fish Invertebrates Plants (estimate) Total 219 145 62 8 64 310 821 21 13 4 5 3 47 14 2 5 1 22 364 1263 383 54 32 10 14 1 3 1 18 56 149 19 5 229 11 11 1 1 68 2006 1 24881 3 28993 100 A number of international initiatives are in place to describe and document species at the global level. The WCMC provides information on globally threatened animals and plants, including searchable databases of the IUCN Red Lists. The IUCN Red List of Threatened Plants and Animals provides taxonomic, conservation status and distribution information on species that have been evaluated using the IUCN Red List categories. In general, the Red List of Threatened Plants and Animals provide information on the relative threat and risk of overall extinction. The rate of decline and population status are considered for categorizing species as â€Å"Critically Endangered†, â€Å"Endangered†, or â€Å"Vulnerable†. The 1996 Red List also includes information on species that are categorized as â€Å"Extinct†, â€Å"Extinct in the Wild†, â€Å"Lower Risk†, and â€Å"insufficient data†. Insufficient data is for the species that cannot be assessed or information on the species in not available. Data and information on birds are available from Birdlife International. The National Red Data Books, on the other hand, provide information on the national flora and fauna that are subjected to highest risk of extinction. The 1996 IUCN Red List of Threatened Animals includes 7,123 threatened species including Extinct, Extinct in the Wild, Critically Endangered, Endangered, Lower Risk and Data Deficient. Out of the total, 639 species are believed to be either Extinct (E) or Extinct in the Wild (EW). Similarly, 5,205 species are classified as Endangered (EN), or Vulnerable (VU) or at Lower Risk (LR). In addition, 1279 species are classified as Data Deficient (DD). Vulnerable species are further subdivided into conservation dependent (134 species), near threatened (1997 species), and least concern (973 species). The 1997 IUCN Red List of Threatened Plants include 33,798 species that includes Extinct (Ex), Extinct/Endangered (Ex/E), Endangered (E), Vulnerable (V), Rare (R), and Intermediate. The 1997 IUCN Red Lists of Threatened Plants and Threatened Animals are presented in Fig. 2 and Fig. 3, respectively. . 11 4070 380 371 14504 6522 Ex Ex/E E V R 7951 I Fig. 2. The 1997 IUCN Red List of Threatened Plants (UNEP, 1999) Fig. 3 IUCN Red List of Threatened Animals by Continents (UNEP, 1999) In 1994, WCMC, in collaboration with IUCN, UNEP, and WWF, published a biodiversity data source book, available in both tabular and map format, providing information on country species diversity, threatened species by country, national red data books, major food crops by country, marine resources, forest in the tropics, and national protected areas and systematics collections. SPECIES 2000 initiative of the International Organization of Plant Information (IOPI) provides an index of the world’s known species. The project aims to provide a uniform and validated quality index of names of all known species for use as a practical tool. This is an electronic database of species list, which provides a database of species index and special annual checklist available through electronic media (i. e. internet and CD). SPECIES 2000 can be accessed in www. species2000. org 12 CAB International is well known for providing abstracts of internationally published scientific research literature. Plant sciences program of CAB International covers information on all â€Å"plant species of economic importance†. A detailed list of species can be found in the â€Å"list of proposed species for Global Module of Forestry Compendium†. The information can be accessed from www. cabi. org. The World Species List (WSL), Plants, Animals and Microbes, established in 1994, also maintains data on species including animals, plants, microbes and endangered species that can be accessed from http://envirolink. rg/species/. 4. 4 Genetic Data Data and information on genetic diversity are available at three levels: Genetic variability between individuals within population; Genetic variations among populations within species; and Diversity among species. Genetic resources data are basically a repository of samp les of living materials of animals, plants, fungi, or micro-organisms, generally in a dormant or other phase in which they are not actively growing (Hawksworth, 1995). Genetic resources information are collected mainly to ensure the conservation of genetic diversity in the future, the main purpose of which is to use it for breeding purposes. The collection can also be used as a source material for its characterization and evaluation. Thus, it is extremely important to conserve adequate stocks followed by regular monitoring and updating. The collections might include stores of gametes, pollen, seeds, spores, tissue cultures and embryos (Hawksworth, 1995). The storage can be maintained in long-term storage facilities as well as in field gene banks. Materials that are not possible to maintain in the dormant form can be maintained in field gene banks, as in the case of some cultivated crops (IPGRI, 1993). The following table provides information on the types of genetic resources collection. Table 8. Types of genetic resources collection Plant genetic resource Animal genetic resource Microbial genetic collections collections resource collections Seed samples Embryos and Cultures of algae, Spore samples semen under bacteria, fungi Pollen samples cryogenic storage Protozoa and Field gene banks Groups of living viruses as well as Embryos animals kept under materials derived Tissues supervision in an from them in the Cell suspensions exclusive area form of cDNA, etc. Networks of plasmids, vectors, breeding groups cell lines etc. 13 The conservation of genetic resources can be managed in situ or ex situ. In situ conservation is maintained in their original habitat and reproducing within the environment in which they evolved and continue to do so. Ex situ conservation is maintained outside their habitats, stored in a reproductively dormant condition. Worldwide over 150 major crop gene banks are held by international, regional, and national institutions, both public and private (Hawksworth, 1995). International Agricultural Research Centres (IARCs) by the Consultative Group on International Agricultural Research (CGIAR) concentrate on land races and cultivars of particular crops and their wild relatives while the storage of seed and other propagules of wild plants is the primary focus of most botanic garden gene banks. Collectively, CGIAR centers hold the largest ex situ collection in the world with some 510,000 accessions (about 10% of the total holdings), but this is believed to correspond to approximately 35% of all accessions held in ex situ collections (FAO, 1994). Regional gene banks include the Nordic Gene Bank and the Southern African Development Community (SADC) Gene Bank. Few examples of national gene banks include the National Bureau of Plant Genetic Resources (India), the plant Genetic Resources Centre (Ethiopia), the M. I. Vavilov Institute of Plant Industry (Russia), and the United States Plant Germ Plasm System (Plucknett et al. 1987). A sizable number of botanic gardens and arboreta are also serving as a seed bank. There are about 528 botanic gardens and arboreta having a seed bank (Hawksworth, 1995). What is the minimum requirements of genetic variation in wild species that need to be stored for the future is a question that has not yet been answered. However, there is a general agreement on the fact that the current system of germplasm collections (mainly seed banks) does not provide an adequate representation of the world’s flora. Some species is well represented while others are not. For example, less than 1% of the world’s plant species comprise more than 60% of the accessions (Halloy, 1990). Similarly, there are 333,413 accessions of rice (Oryza sativa) alone (WCMC, 1992). In contrary to this, the existing gene banks contain a mere 0. 5% of the species actually used by humans. The genetic resources collections of animal husbandry are poorly represented. For example, there are only a few genetic resouce collections of local wild populations of salmon (Salmo salar) from different rivers in Norway and Iceland (Gausen, 1993). In several countries one or more of the indigenous breeds of livestock are represented in genetic resource collections, organized in ways, which reflect the livestock traditions of that country, without having collections from other countries (Hawksworth, 1995). Efforts are being placed to store microbial collections that are important for both biosystematics and human utilization. The World Data Center for Microorganisms (WDCM) holds a database of 786,328 microorganism strains held by 482 collections from 58 countries of which 44% are fungi including yeasts, 43% bacteria, 2% viruses, 1% live cells and 10% others i. e. plasmids, plant cells, and algae (Sugawara et al. 1993). Fur ther 35% of all strains are held by only ten collections (Hawksworth, 1995). The World Federation of Culture Collections (WFCC) coordinates the activities of culture collections at the global level. There are other organizations at regional and international levels, such as the European Culture Collection Organization (ECCO), Microbial Strain 14 Data Network (MSDN), and the Microbian Resource Centers (MIRCENs) of UNESCO, actively involved in culture collections. International Plant Genetic Resources Institute (IPGRI) is also involving in setting priorities for research and inventory and furthering development of a network of national and regional centers for plant germplasm conservation. 4. Biological reference collections Biological reference collections comprise of permanently preserved specimens, recording and photographs maintained in museums, universities, botanic gardens, zoological and similar institutions or by individual scientists. Such collections are the major tools n ecessary for basic investigation and assessment of biodiversity. Duckworth et al. (1993) estimate that there are some 2. 5 billion specimens in preserved biological reference collections, out of which around 2 million museum specimen records are now available in the Internet (Mille, 1993). There are almost 1,600 botanic gardens and arboreta worldwide and majority of the gardens are located either in Europe or in North America (Hawksworth, 1995). A total of 431 botanic gardens are found in North America alone. This clearly indicates that the distribution and dimensions of biological reference collections is skewed towards developed countries in temperate regions. Nevertheless, significant holdings are being built up in less developed regions; for example, the natural history museum of Zimbabwe holds 5. 3 million specimens representing at least 58,000 different species (Cotterill et al. 1993). The total number of accessions of taxa held in botanic gardens is over 3. 2 million consisting of 80,000 species (WWF and IUCN). This represents about 30% of the known species of flowering plants and ferns and 25% of those estimated in the world. The global database maintained by Botanic Gardens Conservation International (BGCI) has already documented holdings of 250,000 accessions and includes records from over 350 institutions, representing about 30,000 species (Leadley et al. 1993). Data held by BGCI indicate that the floras of many major tropical and sub-tropical continental countries, such as Brazil, Colombia, Indonesia, and Zaire as well as othe rs especially in Africa and South America are poorly represented in botanic garden collections. The floras of North America, temperate South America, and Asia, Australia and New Zealand and South Africa are well represented. Also well represented are the endemic floras of many oceanic island groups, especially Macronesia, the Mascarene Islands and Hawaii. Usually, exotic species are given priority in many botanic gardens for aesthetic purposes. A recent trend, however, is to focus on and give priority to the cultivation of indigenous species particularly those that are threatened or endangered. This novel initiative, appreciated by many, will add significantly to the scientific as well as conservation value to the endemic species recourses. 15 5. Major International Conventions The following sub-sections provides brief descriptions on the major international conventions. CBD: Convention on Biological Diversity: The Convention on Biological Diversitys objectives are the conservation of biological diversity, the sustainable use of its components and the fair and equitable sharing of the benefits arising out of the utilization of genetic resources. The Convention is thus the first global comprehensive agreement to address all aspects of biological diversity: genetic resources, species, and ecosystems. It recognizes for the first time that the conservation of biological diversity is a common concern of humankind and an integr al part of the development process. To achieve its objectives, the Convention in accordance with the spirit of the Rio Declaration on Environment and Development promotes a renewed partnership among countries. Its provisions on scientific and technical cooperation, access to genetic resources, and the transfer of environmentally sound technologies form the foundations of this partnership. As of January, 2000, 176 countries have ratified the convention. CMS: Convention on Migratory Species The Convention on Migratory Species (CMS) aims to protect those species of wild animals that migrate across or outside national boundaries. This includes conservation of terrestrial, marine and avian species over the whole of their migratory range. The convention was concluded in 1979 and came into force on 1 November 1983. As of December 1999, 68 states have ratified the convention. CITES: The Convention on International Trade in Endangered Species of Wild Fauna and Flora CITES, is an international treaty drawn up in 1973 to protect wildlife against overexploitation and to prevent international trade from threatening species with extinction. The treaty entered into force on 1 July 1975 and now has a membership of 146 countries. Ramsar Convention: Convention on Wetlands of International Importance The Convention on Wetlands, signed in Ramsar, Iran, in 1971, is an intergovernmental treaty that provides the framework for national action and international cooperation for the conservation and wise use of wetlands and their resources. There are presently 117 Contracting Parties to the Convention. The World Heritage Convention The Convention Concerning the Protection of the World Cultural and Natural Heritage (the World Heritage Convention) was adopted by the General Conference of UNESCO in 1972. As of October 1999, more than 158 countries have signed the convention. This is one of the most universal international legal instruments for the protection of the cultural and natural heritage. 16 6. International Efforts The following are the discussion on the major initiatives of generating and maintaining biodiversity data and information at the global level. BIONET BONET (Biodiversity Action Network) was established in 1993. BIONET aims â€Å"to help build international agreement among governments on concrete actions and targets needed to achieve the objectives of the CBD, with a special focus on forests and marine/coastal systems and to help catalyze specific national- level action to implement the CBD†. Its mission is to advocate the effective implementation of the Biodiversity Convention worldwide, primarily through coordinated, joint NGO programs and information dissemination designed to catalyze governmental action. For additional information please refer to Appendix-1. DIVERSITAS Diversitas programme of IUBS (International Union of Biological Sciences), SCOPE (the Scientific Committee on Problems of the Environment) of the International Council of Scientific Unions (ICSU) and UNESCO was initiated in 1992. DIVERSITAS attempts â€Å"to inventorying and monitoring of biodiversity at the global level†. It has 3 main themes: (i) inventorying and monitoring of overall biodiversity at all levels from genes to ecosystems incorporating both marine and terrestrial ecosystem, (ii) dentify scientific issues and promote research requiring international coordination on the ecosystem function of biodiversity, the origins, maintenance and the practical consequences of current changes on the natural and managed ecosystems that support mankind, and (iii) develop prioritized agendas for research. For additional information please refer to Appendix-1. CENPLANK The Centre for Plankton Collection, Sorting and Identification (CENPLANK) of Szczecin and Gynia, Poland, is an international project, the objective of which is to focus on long-term changes in the status of coastal marine ecosystems using plankton as a means of inventorying and understanding variability in the species biodiversity and abundance levels of ichthyplankton (fish, egg and larvae) and zooplankton components of large marine ecosystems. For additional information please refer to Appendix-1. FISHBASE The FISHBASE project developed by ICLARM and FAO is a database of fishes that provides information on nomenclature, distribution, ecology, reproduction, growth and mortality. For additional information please refer to Appendix-1. FOREST RESOURCES ASSESSMENT (FRA): FRA-2000 of Food and Agricultural Organization of the United Nations aims to perform a global analysis of the distribution of forest ecosystem. Forest resources assessment and deforestation data are available for 1980 and 1990 in a country by country basis. For additional information please refer to Appendix-1. 17 GBIF: The Global Biodiversity Information Facility (GBIF) was proposed by the OECD Megascienc e Forum working group on biological informatics subgroups for biodiversity informatics. The broad goal of the GBIF is to provide the most up-to-date and thorough biodiversity information in timely manner to policy- and decision makers, science and society, in all countries. For additional information please refer to Appendix-1. GOOS Global Ocean Observing System (GOOS) was set up by UNESCOs International Oceanographic Commission. It is a permanent international system for gathering, processing and analyzing oceanographic observation from the open ocean and from coastal and shelf seas. For additional information please refer to Appendix-1. GTOS The Global Terrestrial Observing System (GTOS) is a joint initiative by the FAO, WMO, UNEP, UNESCO and the International Council of Scientific Unions (ICSU). GTOS aims â€Å"to provide scientific coordinated, permanent, observational framework with adequate spatial coverage and temporal continuity to produce data to enable to detect, quantify, locate and understand changes in the capacity of terrestrial ecosystems to support sustainable development†. For additional information please refer to Appendix-1. ICTVdB The database of ICTVdB (International Committee on Taxonomy of Viruses DataBase) is an Index of Virum authorized by ICTV and has been constructed by Cornelia BuchenOsmond, Bioinformatics Group, Australian National University. The index provides a list of approved virus names linked to virus descriptions coded from information in Virus Taxonomy and includes updates subsequently approved by ICTV. For additional information please refer to Appendix-1. IOPI and Species 2000 The International Organization for Plant Information (IOPI) aims â€Å"to produce a checklist of the worlds vascular plant species through a coordinated effort involving numerous specialists and institutions†. IUBS in their 25th General Assembly in 1994 introduced SPECIES 2000 program the goal of which is â€Å"to provide a uniform and validated quality index of names of all known species for use as a practical tool†. The index will be used to provide (i) an electronic baseline species list for use in inventorying projects worldwide; (ii) the index for an Internet gateway to species databases worldwide; (iii) a reference system for comparison between inventories; and (iv) a comprehensive worldwide catalogue for checking the status, classification and naming of species. For additional information please refer to Appendix-1. 18 ISIS The International Species Inventory System (ISIS) is a global network designed to (i) help the management of zoological collection; and (ii) enable zoos to meet their increasing conservation responsibilities. The ISIS maintains a centralized computer database of census, demographic, genealogical and laboratory data for wild species held in captivity. For additional information please refer to Appendix-1. LME The Large Marine Ecosystem program (LME) aims to monitor Large Marine Ecosystem consisting of fish, plankton, marine mammals and birds by coastal nations. The principal focus of which, however, is on fish. For additional information please refer to Appendix1. MICRENS MIRCEN (Microbial Resources Centres) program of UNESCO is a network of existing academic and/or research institutes in developed and developing countries. These centres, in co-operation with the concerned National Commissions of Member States and governmental authorities, participate in a global collaborative network effort to: provide a global infrastructure which would incorporate national, regional, and interregional co-operating laboratories geared to the management, distribution, and utilization of the microbial gene pools; reinforce the conservation of microorganisms, with emphasis on rhizobium gene pools, in developing countries, with an agrarian base; foster the development of new inexpensive technologies native to specific regions; promote the economic and environmental applications of microbiology; and serve as focal centres in the network for the training of manpower. For additional information please refer to Appendix-1. Systematics Agenda 2000 International SA 2000 is a proposal of discovery and research proposed by a Consortium of three international societies of systematic biologists: the American Society of Plant T axonomists, the Society of Systematic Biologiest and the Willi Hennig Society in cooperation with the Association for Systematic Collection. The Systematics Agenda 2000 International aims â€Å"to promote systematic/taxonomic research in all countries and regions in order to support ongoing activities to conserve and sustainably use their biodiversity†. The main activities will be to develop international programs of systematic inventorying, phylogenetic research, the creation of systematic knowledge bases, and the promotion of systematic infrastructure and training. For additional information please refer to Appendix-1. 19 Trichoptera World Checklist The checklist is maintained by the Trichoptera Checklist Coordinating Committee and the searchable database is hosted by Clemson University of USA. For additional information please refer to Appendix-1. Besides above, the following initiatives are also worth mentioning. Bin-21: Biodiversity Information Network; Biome Summaries maintained by SI/MAB program of Smithsonian Institution; Forestry compendium published by CAB International; ETI: Expert center for Taxonomic Identification, University of Amsterdem is a database describing all existing animals and plants of the world in digital form; The World Heritage List from UNESCO; Frontier forests of the world by WRI; Biodiversity â€Å"Hot Spots† by Conservation International; and Protected areas database, 1997 UN list of protected areas, conservation database of species, forest, marine and national biodiversity profiles, the world list of threatened trees, The 1996 IUCN red list of threatened animals and threatened plans of the world, world distribution of coral reefs and mangroves maintained by WCMC. 7. Selected Global Biodiversity information centres. The following is a list of selected global biodiversity information centres. This is not a comprehensive list but provides information on the major initiatives. ) 2) 3) 4) 5) 6) 7) 8) 9) 10) 11) 12) 13) BirdLife International Botanic Gardens Conservation International Conservation Inernational CAB International Consultative Group on International Agricultural Research Clearing house mechanism of the Convention on Biological Diversity European Environment Agency Food and Agriculture Organization of the United Nations International Council of Scientific Unions International Centre for Living Aquatic Resources Management International Institute for Applied Systems Analysis International Plant Genetic Resources Institute International Species Information System 14) IUCN The World Conservation Union 15) National Oceanic and Atmospheric Administration 16) The Nature Conservancy 17) TRAFFIC International 18) UNEP Global Resource Information Database 19) UNEP International Environmental Information System 20) United Nations Educational, Scientific and Cultural Organization 21) United Nations Statistical Division: UNSTAT 22) United States Geological Survey 23) Wetland Internati onal 24) World Conservation Monitoring Centre For detailed information please refer to Appendix-1. 20 8. Resources on the Web Increasingly more and more global biodiversity data and information are available on the web. Appendix-1 presents a list of biodiversity resources on the web. 9. Present Direction Considering the enormous amount and varieties of biodiversity data and information, it is difficult to generalize the present direction of these datasets, however, the general trend is that majority of the data are increasingly available in digital form. The recent trend is that many of these datasets are being collected, maintained and/or distributed using Internet. User friendly Internet mapping techniques are emerging in which a user could prepare and print a map based on his or her criteria. A sizeable number of biodiversity data are also available in CDs. The available datasets are biased i. e. detailed datasets are available for few parameters while a limited amount of data are available for others. However, core data sets are improving, expanding and becoming more easily available. More encouragingly, a number of INGO’s such as WWF, IUCN, Conservation International, and Wetland International are actively contributing to the generation and maintenance of global biodiversity data and information. 10. Problems/Obstacles Problems and obstacles of the availability and accessibility of global biodiversity data are vast and varied. This is primarily because biodiversity data comes from different disciplines and the data volume is extremely large. Moreover, biodiversity data are represented by terrestrial, marine and freshwater ecosystems ranging from ecosystem to genetic levels, thus making it difficult to compile and distribute all the data globally. It is hard to generalize problems and obstacles of biodiversity data and information but a common pattern observed is that the barriers to the availability and accessibility of these products are of the social characteristics rather than technical. For example, many organizations and individuals generating these datasets are reluctant to share available data and information in the fear of loosing their importance in the future. They also feel ownership of the data and reluctant to share with others. A common bias has been observed in collecting and maintaining biodiversity data and information at the global level. Less data are available on utilization aspects of biodiversity conservation compared to conservation. Similarly, more detailed data sets are available for some species as opposed to very limited amount of data for others. Problems and obstacles of biodiversity data and information can be summarized into the following two broad categories. 21 1. Technical Lack of capabilities: Users are unable to use the data; Some of the available data are outdated. In some cases we are working with 70’s and 80’s data in the absence of regular monitoring mechanism. Species data/information is inaccurate and in many cases contradictory primarily because it is extremely difficult to inventory all species on Earth; The availability of coarse resolution digital data with a spatial resolution of 1 KM to 16 KMs. These data sets have little meaning at the implementation level; Lack of basic biological knowledge on species and their variability; Poor understanding of genetics and population biology of the taxa in question; Lack of appropriate techniques for long-term preservation of specimens and genetic resources; Methodology/software not fully developed to collect and manage large volume of biodiversity data; Although collections of some of the world’s major crops are extensive and relatively secure, the situation for many other crop and tree gene pools is far less satisfactory; Biodiversity sample surveys and validation are difficult to implement internationally; Unknown data quality: very little information is available about data quality; Data conversion is a problem because of the incompatible data format; Lack of data consistency including both spatial and temporal; and Quality control of the data available on the Internet is an issue needs closer attention. Many organizations an d scientists are not willing to placed their primary data and informa tion on the web. 2. Management Lack of knowledge of existence: available datasets are not known to the user communities; Lack of willingness to share: the importance of data and information is not fully realized; Information does not meet user requirements because of incorrect format, inadequate documentation, poor quality data, not scientifically credible etc. Data acquisition is being carried out independent of the interest of end users; Not enough feedback and validation during the process of data collection among data collectors, collators, disseminators and users; High cost involved in data collection, constant update, and regular monitoring; Inadequate resources available to discover, describe and catalogue the species of organisms found on Earth; Lack of secure funding and funding mechanism especially in the long term; Shortage of trained people to collect and classify specimens data; Poor social and political awareness on the use of global biodiversity data; and Poor awareness of the strategic and long-term value of genetic resource collections among policy makes researchers and potential users. 22 Poor accessibility of global biodiversity data and information has been cited as one of the major problem for the use of the data for decision-making. The accessibility is hindered by numerous factors, including the following: The cost associated with the data; Restricted access; Lack of knowledge of existence; Lack of integration; and The poor channels of communication. 11. Recommendations for Future directions The following are the set of recommendations for future directions. 1. Data generation is a long-term process that calls for constant commitment from the concerned agencies and individuals. At this point, it is necessary to assess biodiversity data and information already available within existing collections and identification and prioritization of missing or under represented species, geographic regions and environments; 2. Development of a framework and guidelines for future global biodiversity database development is necessary to improve the quality and usefulness of the data; 3. Greater efforts are necessary to generate new global biodiversity datasets, maintain the existing ones, distribute the available data dynamically and use the data appropriately; 4. It is very important to ensure that the resulting information is useful and used by their target audiences. Target audiences might include policy and decision makers, science and society across the globe. One of the basic requirements to achieve this is to improve communication between data producers and users. 5. Concerted effort is essential towards the development and use of technological, sociological, organizational tools and approaches for the dynamic acquisition, indexing, modeling, dissemination, storage, querying, retrieval, visualization, integration, analysis, synthesis, sharing, and publication of global biodiversity data and information. 6. Partnership and collaboration is necessary to maximize benefits. To achieve this, distributed data collectio n approach should be adopted, wherever possible; 7. Availability of higher resolution (better resolution) data is needed in many cases. This could be facilitated by the use of satellite data such as Landsat TM, SPOT, IRS WIFS, and MODIS; 8. Multi-scale approach of data generation should be adopted so as to collect 1:1 million data at the global level, 1:500K to1:250K at the regional level; 1:250K to 1:100K at the sub-regional level, 1:50K at the national level and 1:10K to 1:5K and better at the local level. Emphasis should be placed in generating data that are useful at the national level; and 9. Development of improved management methods for long-term secure conservation, including the maintenance of genetic integrity is necessary. The use of existing genetic collections as part of sustainable development is equally important. 23 Summary An attempt has been made to review the availability and accessibility of global biodiversity data and information. Published reports and Internet resources were the major sources of information for the review. This is by no means a comprehensive review of all the available global biodiversity data and information. The availability and accessibility of global biodiversity data and information have been described under five main categories, namely: global data, conservation area data, species data, genetic data and biological reference collections. Because biodiversity data nd information are vast and varied, it is extremely difficult to generalize the findings. However, it was evident that majority of the data are increasingly available in digital form. The available datasets are biased i. e. detailed datasets are available for few parameters while a limited amount of data are a vailable for others. Similarly, available datasets are concentrated in developed countries in the temperate regions. In general, core data sets are improving, expanding and becoming more easily available. More encouragingly, a number of INGO’s such as WWF, IUCN, Conservation International, and Wetland International are actively contributing to the generation and maintenance of global biodiversity data and information. Users of global biodiversity data include national institutions, regional groupings, international institutions, international funding agencies, bilateral development agencies, international environmental and conservation groups and scientific communities. The barriers to the availability and accessibility of global biodiversity data and information are of the social characteristics rather than technical. Problems and obstacles in collecting, maintaining and distributing biodiversity data and information have been listed. A set of recommendation to improve the present situation has been proposed. 24 References: Bailey, R. G. , 1989. Ecoregions of the Continents. U. S. Department of Agriculture, Forest Service, Washington D. C. , USA Bisby, F. A. , 1995. Characterization of Biodiversity, Global Biodiversity Assessment. United Nations Environment Programme, Nairobi, Kenya. Chauvet, M. , Oliver, L. , 1993. La biodiversite Enjeu planetaire. Preserver notre patrimoine genetique. Editions Sang de la Terre, Paris. Cotterill, E. P. D. , Hustler, C. W. , Sparrow, A. L. , and Broadley, D. G. , 1993. Conservation of biodiversity in Africa: the role of Natural History Museum of Zimbabwe. The Zimbabwe Science News 27:32-34. Cox, C. B. , and Moore, P. D. , 1993. Biogeography: An ecological and evolutionary approach. Blackwell Scientific Publications, London. Duckworth, W. D. , Genoways, H. H. , and Rose, C. L. , 1993. Preserving Natural Science Collections: Chronicle of our environmental heritage. National Institute for the Conservation of Cultural Property, Washington, DC, USA. FAO, 1994. STRIPE Study on Genetic Resources in the CGIAR, AGR/TAC:IAR/94/2. 1 The Secretariat, Aprial 1994, Rome. Green, M. J. B. , and Paine, J. , 1997. State of the world’s protected areas at the end of the twentieth century. Paper presented at IUCN World Commission on Protected Areas Symposium on â€Å"Protected Areas in the 21st . Century: From Islands to Networks†, Albany, Australia, 24-29 November, 1997. Halloway, J. , 1983. The role of taxonomy, reference works and insect collections in tropical ecology. Antenna 7:50-53. Hawksworth, D. L. , 1995. The Resources Base for Biodiversity Assessments. Global Biodiversity Assessment, United Nations Environment Programme, Kenya. Hayden, B. P. , Ray, C. G. , and Dolan, R. , 1984. Classification of coastal and marine environments. Environmental Conservation. 11:199-207. Hengeveld, R. , 1990. Dynamic Biogeography. Cambridge Unicvversity Press, Cambridge, UK. Holdridge, L. R. , 1967. Life Zone Ecology. Tropical Science Center, San Jose, USA IUCN (International Union for Conservation of Nature and Natural Resouces) 1998. 1997 United Nations List of Protected Areas. Prepared by WCMC and WCPA. IUCN, Gland, Switzerland and Cambridge, UK. 1xii + 412pp. 25 IUCN (International Union for Conservation of Nature and Natural Resouces), 1994. IUCN Red List Categoeis. IUCN, Gland. IPGRI, 1993. Diversity for Development. The Strategy of the International Plant Generic Resources Institute. International Plant Genetic Resources Institute, Rome. Leadley, E. , Wyse Jackson, D. , and Wyse Jackson P. , 1993. Developing the BGCI database of botanic gardens and their collections worldwide. Botanic Gardens Conservation News 2 (2): 61-64. Lovejoy, T. E. , 1980a. Conservation Biology: An evolutionary-ecological perspective, v- ix. Sinauer Associates, Suderland, USA. Lovejoy, T. E. , 1980b. Changes in Biological Diversity. The Global 2000 report to the president. Vol. 2 (the technical report), Penguin Books, USA. McNeely, J. A. , Miller, K. R. , Reid, W. Mittermeier, R. and Werner, T. , 1990. Conserving the World’s Biological Diversity. IUCN, WRI, World Bank, WWF-US, CI, USA. Miller, S. E. , 1993. Biological Collections databases available on Internet. Pacific Science Association Bulletin 45:14-15. Norse, E. A. , Rosenbaum, K. L. , Wilcove, D. S. , Wilcox, B. A. , Romme, W. H. , Johnston, D. W. , and Stout, M. L. , 1986. Conserving Biological Diversity in our Natural Forests. The Wilderness Society, Washington, USA. Olson, J. S. , Watts, J. A. , and Allision, L. J. , 1983. Carbon in Live Vegetation of Major World Ecosystems. Oak Ridge National Laboratory, Oak Ridge, USA Paine, J. R. , 1997. Status, trends and future scenarios for forest conservatin including protected areas in the Asia-pacific Region. Asia-Pacific Forestry Sector Outlook Study Working Paper Seris No. 4, FAO, Rome. Plucknett, D. L. , Smith, N. J. M. , Williams, J. T. , and Anishetty, M. N. , 1987. Gene Banks and the World Food. Princeton University Press, Princeton, USA. Reid, W. V. , and Miller, M. R. , 1989. Keeping Options Alive. World Resources Institute, Washington, USA. Stanton, N. L. , and Lattin, J. D. , 1989. In defence of species. Bioscience 36:368-373 Sugawara, H. , Ma, J. , Miyazaki, S. , Shimura, J. and Takishima, Y. (eds), 1993. Word directory of collections and cultures of Microorganisms: Bacteria, fungi, and yeasts. 4th . Edn. WFCC, World Data Cemter on Micororganisms, Japan. Takhtajan, A. , 1969. Flowering plants, Origins and Dispersal. Oliver and Boyd, Edinburgh, UK. Udvardy, M. D. F. , 1975. A Classification of the Biogeographical Provinces of the World. IUCN Occasional Paper No. 18 IUCN, Gland, Switzerland. 26 UNEP, 1999. Global Environment Outlook-2000. United Nations Environment Programme, Nairobi, Kenya. UNEP, 1995. Global Biodiversity Assessment. United Nations Environment Programme, Nairobi, Kenya. UNEP, 1993. Guidelines for Country Studies on Biological Diversity. United Nations Environment Programme, Nairobi, Kenya. WCMC, 1992. Global Biodiversity: Status of Earth Living Resources. World Conservation Monitoring Center, Cambridge, UK. Wilson, E. O. , 1984. Biophilia. Harward University Press, Cambridge, USA Wilson, E. O. , and Peters, F. M. , (eds), 1988. Biodiversity. National Academy Press, Washington DC. USA. 27 Appendix-1: List of Biodiversity Resources on the Web Agenda 21 Alice Software: for creating and managing biodiversity databases

Monday, March 2, 2020

How to Pass the CAHSEE Expert Strategy Guide

How to Pass the CAHSEE Expert Strategy Guide SAT / ACT Prep Online Guides and Tips Do you go to school in California? Chances are you’ve heard of the CAHSEE – the exam all Californians need to take to graduate high school. You might be wondering how to pass the CAHSEE. In this post, we will explain what the CAHSEE tests, what you need to do to pass, and how to study for it. What Is the CAHSEE? The CAHSEE (California High School Exit Examination) is an exam all California high school students must pass to earn a high school diploma. Students take the exam for the first time sophomore year, and retake it in later years if they don’t pass. The exam has two sections – math and English Language Arts (ELA). Most students, around 80% each year, pass the exam on their first try. In 2014, 85% of sophomores passed math and 83% of sophomores passed ELA. However, the pass rate is significantly lower for English Language Learners (ELLs) and students with disabilities. In 2014, 42% of special education sophomores passed math, and 39% passed ELA. Only 54% of ELLs passed math, and 38% passed ELA. The test is only given in English, making the ELA portion especially challenging for students still learning the language. The CAHSEE is not designed to be an extra burden or especially difficult, and students are expected to pass with the basics of what they learn in high school. The goal of the CAHSEE is to ensure all California high school graduates have met a certain skill threshold. However, if you’re worried about passing, this guide will give you the tools you need for success – and a California high school diploma. What If I Fail? Before we dig into the study guide, it’s important to know what happens if you fail the CAHSEE. You will take the CAHSEE for the first time sophomore year. If you don’t pass a section, you will just have to retake that section – for example, if you pass ELA but fail math, you will only have to take math again. If you fail both sections, you will retake both. You can retry the CAHSEE twice in junior year and up to five times senior year. So don’t stress if you don’t pass during sophomore year – you will get plenty of chances to retry the test. If you don’t pass by graduation, you can try for up to two school years after. Depending on your district, there may be summer school or fifth year options to help you pass the CAHSEE and complete high school. Contact your school to find out their policy for students who don’t pass CAHSEE by graduation. How To Pass The CAHSEE: English The English, or ELA, section is mostly multiple-choice, though there is a written response section as well. It covers reading and writing topics. To pass, you need to be able to comprehend and analyze passages, and also know the basics of English grammar and writing strategies. If you don't do much reading in your spare time, try to do a little every day, even if you're just reading articles online or books for fun. Daily reading can help you get better at reading comprehension, even on standardized tests like the CAHSEE. This section is untimed, so unlike high-stakes tests like the SAT and ACT, you don’t have to worry about pacing. The reading topics are: Word Analysis (7 questions) Reading Comprehension (18 questions) Literary Response and Analysis (20 questions) The reading questions mostly consist of reading passages and answering questions about them. The writing topics are: Writing Strategy (12 questions) Writing Application (1 essay question) English Language Conventions (15 questions) This comes to a total of 72 multiple-choice questions, plus 7 additional unscored questions sprinkled in used to test out new question types. The ELA section is given a scaled score between 275 and 450. A scaled score means they translate the raw scores (a.k.a. how many points you get from right answers) into a number between 275 and 450. Anything above 350 is passing. There is not a set amount of raw points you need, since scaling can change from test to test. So you should aim to get a majority of the questions correct, though you don't need to shoot for perfection. Your essay will be assigned a score from 1 to 4, with 4 being best. Two people will read it, and their scores will be averaged. Your essay won’t be scored if it is illegible, not in English, or off-topic. How To Pass the CAHSEE: Math The math section of the CAHSEE is all multiple-choice questions. It is untimed, so again, you don’t have to worry about rushing through. However, there are no calculators allowed, so you have to do all math work by hand. If you rely on calculators to do multiplication and division, you have to practice doing math on paper. To pass, you also need to have a pretty solid understanding of math through basic geometry and Algebra I. Or practice on a chalkboard for some old-school cool. The math section tests the following topics: Probability, Data Analysis and Statistics (12 questions) Number Sense (14 questions) Algebra and Functions: (17 questions) Measurement and Geometry: (17 questions) Algebra 1 (12 questions) Mathematical Reasoning (8 questions) Unscored trial questions (12 questions) This makes for 92 total questions. The math section is also scored between 275 and 450, with anything above 350 passing. Again, aim to get a majority of the questions right, but don't worry about being 100% perfect. CAHSEE Study Guide So now that you know what's on the CAHSEE and how many chances you will have to pass it, how should you study for it? And what can you use? We will show you how to come up with a study plan, what resources to use, and how to get help at school. Score Report = Study Guide After you take the CAHSEE, you will get a detailed report that says how well you did in each topic. For example, it will say how many Algebra and functions questions you got right, in addition to giving an overall math section score. If you failed the CAHSEE the first time, don’t get overwhelmed by the score report saying all the things you did wrong. You don’t have to fix every single mistake to pass – you just need to fix enough to get above 350. Use your score report as a study guide. Start with the sections you missed the most questions on and focus on learning that material first. As an example, say a student got the following score report for math: Probability, Data Analysis and Statistics: 7 / 12 Number Sense: / 14 Algebra and Functions: 3 / 17 Measurement and Geometry: 2 / 17 Algebra 1: 2 / 12 Mathematical Reasoning: 4 / 8 While this student missed points in every section, they have the most work to do in Algebra and Functions, Measurement and Geometry, and Algebra 1. Since those topics build on each other – you need to understand basic algebra before getting Geometry and Algebra 1 – they should start by studying Algebra and Functions, and then move onto Geometry and Algebra 1. Also, those sections also happen to be the largest, with 17 questions each for Algebra and Functions and Measurement and Geometry, and 12 questions for Algebra 1. So if they can improve their scores in those three sections, they will be on track to pass. If they have extra time, they can review the other sections. But they should focus on learning Algebra and Geometry skills and practicing problems in those sections. If you haven't taken the CAHSEE yet, start with the official study guides (which we will link to below) and focus on what is most difficult for you. Gather Your Resources You won't need tons of books to study for the CAHSEE, since there are many resources online. Make sure you have studying basics, though, like a notebook, pen, and earplugs if they help you focus. Before you start studying, you need some materials! Luckily, there is a free, official CAHSEE study guide online and tons of practice questions for each section – way more questions than actually appear on one CAHSEE. 1. Math study guide 2. Math released questions 3. ELA study guide 4. ELA released questions The study guides will walk you through what problems are going to be on the CAHSEE, and what you need to know. Start by reading the study guides before moving onto the practice problems. To do the practice problems, either print them out or look at them on the computer. (You can use a blank notebook to keep track of your answers.) Doing the practice problems is also important so you get used to the format of the CAHSEE. When you correct the problems, don’t just mark what you got wrong and tally your score, try and figure out why you got the question wrong and what you didn’t know. Pretend It's The Real Thing You don’t have to time yourself while practicing, since CAHSEE is untimed, but remember to simulate test conditions by not using a calculator or any outside resources. If you don’t know a question, circle it. Come back to it later and figure out what you would need to know to get the question right. Schedule, Schedule, Schedule Make studying for the CAHSEE part of your weekly schedule. Put it in your calendar like it’s another class or sport. By making CAHSEE studying a set part of your weekly routine, you can retain information from week to week and make sure you get plenty of practice. Also, make sure when you study you find a quiet room without distractions. Whether that means finding a table at your school library or asking your family to give you some space after dinner at night, make sure you find a good study spot. It’s very hard to focus with distractions around, especially other people. Find School Resources Of course, you shouldn’t try to study completely on your own. Your school probably has resources for CAHSEE studying – it’s a goal for every California high school for all of their students to pass and graduate! Some schools have CAHSEE classes you can take. Others have after-school or Saturday study sessions. While it’s not fun to have to give up after-school time for studying, even just a few sessions could help you learn what you need to pass, and you might study faster than you would on your own. Is this the coolest place to spend a Saturday? No. Can it help you pass CAHSEE? Yes. To find out how your school helps students with CAHSEE, go to the guidance counseling office and ask about CAHSEE classes and resources. If your school doesn’t have these, you can find a math and an ELA teacher to help you study. Ask if they can explain topics that you don’t understand, or to help go over practice test answers with you. Some schools also have peer tutoring, and you can ask for help there as well. Special Education If you receive special education services, ask your school’s special education department coordinator about resources for CAHSEE, including accommodations you might not have received that could help you pass. If you normally get accommodations on tests, you should be able to get the same accommodations for CAHSEE. English Language Learners If you’re an English Language Learner, ask your school’s ELL coordinator about accommodations you can get on the CAHSEE, including bilingual dictionaries or a read-aloud test. Remember, it’s in your school’s best interest for all students to pass the CAHSEE. Don’t be shy about tracking down resources that can help you. What’s Next? Also studying for the ACT or SAT? Learn how to improve a low math score. Learn about colleges with the highest admission rates to help start your college planning. Come up with a target SAT or ACT score based on colleges you want to attend. Want to improve your SAT score by 160 points or your ACT score by 4 points? We've written a guide for each test about the top 5 strategies you must be using to have a shot at improving your score. Download it for free now: