Resource Base List
API endpoint that allows base resources to be viewed or edited.
GET /api/v2/resources?format=api&page=27
{ "links": { "next": "http://ihp-wins.unesco.org/api/v2/resources?format=api&page=28", "previous": "http://ihp-wins.unesco.org/api/v2/resources?format=api&page=26" }, "total": 284, "page": 27, "page_size": 10, "resources": [ { "pk": "904", "uuid": "8396e4b6-b961-11e7-bdb3-005056062634", "resource_type": "layer", "polymorphic_ctype_id": "51", "owner": { "pk": 1065, "username": "najet.guefradj", "first_name": "Najet", "last_name": "Guefradj", "avatar": "https://www.gravatar.com/avatar/e5b6ec7203dd9989e1d70a772bb82695/?s=240&d=http%3A%2F%2Fihp-wins.unesco.org%2Fstatic%2Favatar%2Fimg%2Fdefault.jpg" }, "poc": { "pk": 1065, "username": "najet.guefradj", "first_name": "Najet", "last_name": "Guefradj", "avatar": "https://www.gravatar.com/avatar/e5b6ec7203dd9989e1d70a772bb82695/?s=240&d=http%3A%2F%2Fihp-wins.unesco.org%2Fstatic%2Favatar%2Fimg%2Fdefault.jpg" }, "metadata_author": { "pk": 1065, "username": "najet.guefradj", "first_name": "Najet", "last_name": "Guefradj", "avatar": "https://www.gravatar.com/avatar/e5b6ec7203dd9989e1d70a772bb82695/?s=240&d=http%3A%2F%2Fihp-wins.unesco.org%2Fstatic%2Favatar%2Fimg%2Fdefault.jpg" }, "keywords": [ { "name": "Abstraction", "slug": "abstraction" }, { "name": "Groundwater", "slug": "groundwater" }, { "name": "Surface water", "slug": "Surfacewater" } ], "regions": [ { "code": "GLO", "name": "Global" } ], "category": { "identifier": "Ecohydrology" }, "title": "Freshwater abstracted in 2007", "abstract": "This layer represents the volume of freshwater abstracted in 2007 in million cubic meters. Freshwater abstracted refers to the sum of both fresh surface water and fresh groundwater abstracted. Values are also available for other years. Those estimates are provided by the Environment Statistics Section of the United Nation Statistics Division (UNSD).\r\n\r\nFor more information, visit the UN Environment Statistics Section website: https://unstats.un.org/unsd/environment/default.htm. Information on the methodology can be found in the report on International Recommendations for Water Statistics: https://unstats.un.org/unsd/publication/seriesM/seriesm_91e.pdf", "attribution": null, "doi": null, "alternate": "geonode:freshsgtotalabs", "bbox_polygon": { "type": "Polygon", "coordinates": [ [ [ -180.0, -56.5247 ], [ -180.0, 83.14457060000007 ], [ 180.0000000000001, 83.14457060000007 ], [ 180.0000000000001, -56.5247 ], [ -180.0, -56.5247 ] ] ] }, "ll_bbox_polygon": null, "srid": "EPSG:4326", "date": "2017-08-24T08:55:00Z", "date_type": "publication", "edition": "United Nations Statistics Division. UN-Data - Environment Statistics Database. Fresh groundwater abstracted [http://data.un.org/Data.aspx?d=ENV&f=variableID%3a5001. Accessed 28 july 2017]", "purpose": "", "maintenance_frequency": "notPlanned", "restriction_code_type": null, "constraints_other": "Unless otherwise specified, no restriction applies.", "license": { "identifier": "not_specified" }, "language": "eng", "spatial_representation_type": null, "temporal_extent_start": "1990-01-01T09:55:00Z", "temporal_extent_end": "2015-12-31T09:55:00Z", "supplemental_information": "UNSD Environmental Indicators disseminate global environment statistics on ten indicator themes compiled from a wide range of data sources. The themes and indicator tables were selected based on the current demands for international environmental statistics and the availability of internationally comparable data. Indicator tables, charts and maps with relatively good quality and coverage across countries, as well as links to other international sources, are provided under each theme.", "data_quality_statement": "The Environment Statistics Database contains selected water and waste statistics by country. Statistics on water and waste are based on official statistics supplied by national statistical offices and/or ministries of environment (or equivalent institutions) in countries in response to the biennial UNSD/UNEP Questionnaire on Environment Statistics.", "group": { "pk": 74, "name": "IHP-Theme6-Water-education" }, "popular_count": "402", "share_count": "0", "rating": "0", "featured": false, "is_published": true, "is_approved": true, "detail_url": "/layers/freshsgtotalabs:geonode:freshsgtotalabs", "embed_url": "/layers/geonode:freshsgtotalabs/embed", "created": "2020-02-11T11:06:45.204622Z", "last_updated": "2021-02-19T14:30:13.004863Z", "raw_abstract": "This layer represents the volume of freshwater abstracted in 2007 in million cubic meters. Freshwater abstracted refers to the sum of both fresh surface water and fresh groundwater abstracted. Values are also available for other years. Those estimates are provided by the Environment Statistics Section of the United Nation Statistics Division (UNSD). For more information, visit the UN Environment Statistics Section website: https://unstats.un.org/unsd/environment/default.htm. Information on the methodology can be found in the report on International Recommendations for Water Statistics: https://unstats.un.org/unsd/publication/seriesM/seriesm_91e.pdf", "raw_purpose": "", "raw_constraints_other": "Unless otherwise specified, no restriction applies.", "raw_supplemental_information": "UNSD Environmental Indicators disseminate global environment statistics on ten indicator themes compiled from a wide range of data sources. The themes and indicator tables were selected based on the current demands for international environmental statistics and the availability of internationally comparable data. Indicator tables, charts and maps with relatively good quality and coverage across countries, as well as links to other international sources, are provided under each theme.", "raw_data_quality_statement": "The Environment Statistics Database contains selected water and waste statistics by country. Statistics on water and waste are based on official statistics supplied by national statistical offices and/or ministries of environment (or equivalent institutions) in countries in response to the biennial UNSD/UNEP Questionnaire on Environment Statistics.", "metadata_only": false, "thumbnail_url": "http://ihp-wins.unesco.org/uploaded/thumbs/layer-8396e4b6-b961-11e7-bdb3-005056062634-thumb.png?v=fc0581c9" }, { "pk": "1509", "uuid": "9fedb184-3ad9-11ea-9f10-005056062634", "resource_type": "layer", "polymorphic_ctype_id": "51", "owner": { "pk": 1536, "username": "laura.del-val-alonso", "first_name": "Laura", "last_name": "del-Val-Alonso", "avatar": "https://www.gravatar.com/avatar/88e9d5005a660955b9ed98c57474baef/?s=240&d=http%3A%2F%2Fihp-wins.unesco.org%2Fstatic%2Favatar%2Fimg%2Fdefault.jpg" }, "poc": { "pk": 1536, "username": "laura.del-val-alonso", "first_name": "Laura", "last_name": "del-Val-Alonso", "avatar": "https://www.gravatar.com/avatar/88e9d5005a660955b9ed98c57474baef/?s=240&d=http%3A%2F%2Fihp-wins.unesco.org%2Fstatic%2Favatar%2Fimg%2Fdefault.jpg" }, "metadata_author": { "pk": 1536, "username": "laura.del-val-alonso", "first_name": "Laura", "last_name": "del-Val-Alonso", "avatar": "https://www.gravatar.com/avatar/88e9d5005a660955b9ed98c57474baef/?s=240&d=http%3A%2F%2Fihp-wins.unesco.org%2Fstatic%2Favatar%2Fimg%2Fdefault.jpg" }, "keywords": [ { "name": "Groundwater", "slug": "groundwater" }, { "name": "Supply", "slug": "Supply" } ], "regions": [ { "code": "ALB", "name": "Albania" } ], "category": { "identifier": "Groundwater" }, "title": "Albanian supply wells in the DRIN area", "abstract": "This layer provides information about the main groundwater supply wells in the Albanian national segment of the Skadar/Shkoder - Buna/Bojana Transboundary Aquifer System", "attribution": null, "doi": "None", "alternate": "geonode:DRIN_ALB_SupplyWells", "bbox_polygon": { "type": "Polygon", "coordinates": [ [ [ 19.444585685440074, 41.94045675301317 ], [ 19.440765567704737, 42.096988367647995 ], [ 19.548216566672373, 42.09839836345642 ], [ 19.55177366280517, 41.941859074950614 ], [ 19.444585685440074, 41.94045675301317 ] ] ] }, "ll_bbox_polygon": null, "srid": "EPSG:4326", "date": "2020-02-06T10:17:00Z", "date_type": "publication", "edition": "DRIN, 2019. Albanian supply wells in the DRIN area. WINS: Paris, France", "purpose": "Set up the bases for the design of a transboundary groundwater monitoring network under the European Water Framework Directive", "maintenance_frequency": "unknown", "restriction_code_type": null, "constraints_other": "DRIN project", "license": { "identifier": "not_specified" }, "language": "eng", "spatial_representation_type": { "identifier": "vector" }, "temporal_extent_start": "2020-03-10T08:45:00Z", "temporal_extent_end": "2020-03-10T08:45:00Z", "supplemental_information": "No information provided", "data_quality_statement": "The methodology followed is explained in the final report of the DRIN project \"Design and testing of a multi-purpose (transboundary) groundwater monitoring network (Albania and Montenegro)\" (del Val, Carrubba & Mas-Pla, 2019)", "group": { "pk": 118, "name": "Drin-basin" }, "popular_count": "43", "share_count": "0", "rating": "0", "featured": false, "is_published": true, "is_approved": true, "detail_url": "/layers/geonode_ihp_data:geonode:DRIN_ALB_SupplyWells", "embed_url": "/layers/geonode:DRIN_ALB_SupplyWells/embed", "created": "2020-01-19T15:43:05.497000Z", "last_updated": "2021-02-19T14:30:12.704290Z", "raw_abstract": "This layer provides information about the main groundwater supply wells in the Albanian national segment of the Skadar/Shkoder - Buna/Bojana Transboundary Aquifer System", "raw_purpose": "Set up the bases for the design of a transboundary groundwater monitoring network under the European Water Framework Directive", "raw_constraints_other": "DRIN project", "raw_supplemental_information": "No information provided", "raw_data_quality_statement": "The methodology followed is explained in the final report of the DRIN project \"Design and testing of a multi-purpose (transboundary) groundwater monitoring network (Albania and Montenegro)\" (del Val, Carrubba & Mas-Pla, 2019)", "metadata_only": false, "thumbnail_url": "http://ihp-wins.unesco.org/uploaded/thumbs/layer-9fedb184-3ad9-11ea-9f10-005056062634-thumb.png?v=2dd1f3f8" }, { "pk": "171", "uuid": "78d6e5da-e0bd-11e6-8719-005056bf7531", "resource_type": "layer", "polymorphic_ctype_id": "51", "owner": { "pk": 3, "username": "Tales.Carvalho-Resende", "first_name": "Tales", "last_name": "Carvalho Resende", "avatar": "/static/avatars/Tales.Carvalho-Resende/resized/240/Photo_TalesCarvalhoResende.2b1b88521f4c.jpg" }, "poc": { "pk": 3, "username": "Tales.Carvalho-Resende", "first_name": "Tales", "last_name": "Carvalho Resende", "avatar": "/static/avatars/Tales.Carvalho-Resende/resized/240/Photo_TalesCarvalhoResende.2b1b88521f4c.jpg" }, "metadata_author": { "pk": 3, "username": "Tales.Carvalho-Resende", "first_name": "Tales", "last_name": "Carvalho Resende", "avatar": "/static/avatars/Tales.Carvalho-Resende/resized/240/Photo_TalesCarvalhoResende.2b1b88521f4c.jpg" }, "keywords": [ { "name": "Basin", "slug": "basin" }, { "name": "Surface water", "slug": "Surfacewater" }, { "name": "Transboundary", "slug": "transboundary" } ], "regions": [ { "code": "GLO", "name": "Global" } ], "category": { "identifier": "Ecohydrology" }, "title": "Transboundary River Basins around the World", "abstract": "The world’s transboundary river basins span 151 countries, include more than 2.8 billion people (around 42 % of the world’s population), cover 62 million km2 (42 % of the total land area of the Earth), and produce around 22 000 km3 of river discharge each year (roughly 54 % of the global river discharge).\r\n\r\nFrom earlier known transboundary river basin delineations ( 214 transboundary basins identified by UNDESA (1978), 261 by Oregon State University (1999), 263 by OSU (2002), 276 by OSU (2012)) the number has risen to 286.\r\n\r\nFor more information, visit: http://twap-rivers.org/", "attribution": null, "doi": null, "alternate": "geonode:transboundary_river_basins", "bbox_polygon": { "type": "Polygon", "coordinates": [ [ [ -164.47140062099996, -54.74998541999997 ], [ -164.47140062099996, 71.63810509300004 ], [ 145.02916666700003, 71.63810509300004 ], [ 145.02916666700003, -54.74998541999997 ], [ -164.47140062099996, -54.74998541999997 ] ] ] }, "ll_bbox_polygon": null, "srid": "EPSG:4326", "date": "2017-01-21T23:00:00Z", "date_type": "publication", "edition": "UNEP-DHI and UNEP (2016). Transboundary River Basins: Status and Trends. United Nations Environment Programme (UNEP), Nairobi.", "purpose": "", "maintenance_frequency": null, "restriction_code_type": null, "constraints_other": "Unless otherwise specified, the Creative Commons License applies.", "license": { "identifier": "not_specified" }, "language": "eng", "spatial_representation_type": null, "temporal_extent_start": null, "temporal_extent_end": null, "supplemental_information": "Information was collected within the framework of the Transboundary Waters Assessment Programme (TWAP), initiated by the Global Environment Facility (GEF), aimed at creating the first baseline assessment of all the planet’s transboundary water resources.", "data_quality_statement": "/", "group": { "pk": 70, "name": "IHP-Theme2-Groundwater" }, "popular_count": "2816", "share_count": "0", "rating": "0", "featured": false, "is_published": true, "is_approved": true, "detail_url": "/layers/transboundary_river_basins:geonode:transboundary_river_basins", "embed_url": "/layers/geonode:transboundary_river_basins/embed", "created": "2020-02-11T11:06:45.204622Z", "last_updated": "2021-02-19T14:30:13.011467Z", "raw_abstract": "The world’s transboundary river basins span 151 countries, include more than 2.8 billion people (around 42 % of the world’s population), cover 62 million km2 (42 % of the total land area of the Earth), and produce around 22 000 km3 of river discharge each year (roughly 54 % of the global river discharge). From earlier known transboundary river basin delineations ( 214 transboundary basins identified by UNDESA (1978), 261 by Oregon State University (1999), 263 by OSU (2002), 276 by OSU (2012)) the number has risen to 286. For more information, visit: http://twap-rivers.org/", "raw_purpose": "", "raw_constraints_other": "Unless otherwise specified, the Creative Commons License applies.", "raw_supplemental_information": "Information was collected within the framework of the Transboundary Waters Assessment Programme (TWAP), initiated by the Global Environment Facility (GEF), aimed at creating the first baseline assessment of all the planet’s transboundary water resources.", "raw_data_quality_statement": "/", "metadata_only": false, "thumbnail_url": "http://ihp-wins.unesco.org/uploaded/thumbs/layer-78d6e5da-e0bd-11e6-8719-005056bf7531-thumb.png?v=717cb1fa" }, { "pk": "1126", "uuid": "d9c0ebda-46f5-11e8-a93b-005056062634", "resource_type": "layer", "polymorphic_ctype_id": "51", "owner": { "pk": 1275, "username": "adrian.barranco-fabre", "first_name": "Adrian", "last_name": "Barranco-Fabre", "avatar": "/static/avatars/adrian.barranco-fabre/resized/240/20180224_163631.d97d0775e6c3.jpg" }, "poc": { "pk": 1275, "username": "adrian.barranco-fabre", "first_name": "Adrian", "last_name": "Barranco-Fabre", "avatar": "/static/avatars/adrian.barranco-fabre/resized/240/20180224_163631.d97d0775e6c3.jpg" }, "metadata_author": { "pk": 1275, "username": "adrian.barranco-fabre", "first_name": "Adrian", "last_name": "Barranco-Fabre", "avatar": "/static/avatars/adrian.barranco-fabre/resized/240/20180224_163631.d97d0775e6c3.jpg" }, "keywords": [ { "name": "Basin", "slug": "basin" }, { "name": "Drinking water", "slug": "Drinking_water" }, { "name": "Human settlements", "slug": "Humansettlements" }, { "name": "Quality", "slug": "Quality" }, { "name": "Supply", "slug": "Supply" }, { "name": "Surface water", "slug": "Surfacewater" } ], "regions": [ { "code": "GLO", "name": "Global" } ], "category": { "identifier": "Water for human settlements" }, "title": "Grassland Reforestation Practices concerning Phosphorous", "abstract": "To help determine where watershed conservation can help secure water for cities, we estimated the effectiveness of five common conservation strategies: land protection, reforestation, riparian restoration, agricultural best management practices, and forest fuel reduction. For each strategy, we evaluated how effectively it reduces sedimentation and nutrient pollution in more than 2,000 source watersheds that serve over 500 cities. This map shows the potential of cities to do so in four categories: <10km2 is “High”, 10-100km2 is “Medium”, > 100km2 is “Low”. Note that cities that predominately (>0.5) use something other than surface water, or cities that get the significant majority of their water (>0.66) from sources that this strategy cannot help, are classified as “Insufficient scope”.\r\nFor more information, access the Urban Water Blueprint report here: http://www.iwa-network.org/wp-content/uploads/2016/06/Urban-Water-Blueprint-Report.pdf\r\nYou can also visit the Urban Water Blueprint website here: http://water.nature.org/waterblueprint/#/intro=true", "attribution": null, "doi": null, "alternate": "geonode:Refor_P_category_NC", "bbox_polygon": { "type": "Polygon", "coordinates": [ [ [ -149.8921253, -43.52765168 ], [ -149.8921253, 61.21766954 ], [ 174.7646444, 61.21766954 ], [ 174.7646444, -43.52765168 ], [ -149.8921253, -43.52765168 ] ] ] }, "ll_bbox_polygon": null, "srid": "EPSG:4326", "date": "2019-10-24T09:30:00Z", "date_type": "publication", "edition": "McDonald, R.I. & D. Shemie (2014). Urban Water Blueprint: Mapping conservation solutions to the global water challenge. The Nature Conservancy: Washington, D.C.", "purpose": "", "maintenance_frequency": null, "restriction_code_type": null, "constraints_other": "Unless otherwise specified, no restriction applies.", "license": { "identifier": "not_specified" }, "language": "eng", "spatial_representation_type": { "identifier": "vector" }, "temporal_extent_start": "2014-12-31T23:00:00Z", "temporal_extent_end": "2015-12-30T23:00:00Z", "supplemental_information": "The Urban Water Blueprint analyzes the state of water in more than 2000 watersheds and 530 cities worldwide to provide science-based recommendations for natural solutions that can be integrated alongside traditional infrastructure to improve water quality. \r\nThe Urban Water Blueprint has continued to improve its scientific analysis over time, correcting reported errors and improving its methodology", "data_quality_statement": "Updated results are not reflected in the report or website. Anyone considering using the results for analysis or decision-making should contact the Urban Water Blueprint at water@tnc.org to obtain the most current estimates.", "group": { "pk": 72, "name": "IHP-Theme4-Water-for-settlements" }, "popular_count": "55", "share_count": "0", "rating": "0", "featured": true, "is_published": true, "is_approved": true, "detail_url": "/layers/datastore:geonode:Refor_P_category_NC", "embed_url": "/layers/geonode:Refor_P_category_NC/embed", "created": "2020-02-11T11:06:45.204622Z", "last_updated": "2021-02-19T14:30:13.301045Z", "raw_abstract": "To help determine where watershed conservation can help secure water for cities, we estimated the effectiveness of five common conservation strategies: land protection, reforestation, riparian restoration, agricultural best management practices, and forest fuel reduction. For each strategy, we evaluated how effectively it reduces sedimentation and nutrient pollution in more than 2,000 source watersheds that serve over 500 cities. This map shows the potential of cities to do so in four categories: 100km2 is “Low”. Note that cities that predominately (>0.5) use something other than surface water, or cities that get the significant majority of their water (>0.66) from sources that this strategy cannot help, are classified as “Insufficient scope”. For more information, access the Urban Water Blueprint report here: http://www.iwa-network.org/wp-content/uploads/2016/06/Urban-Water-Blueprint-Report.pdf You can also visit the Urban Water Blueprint website here: http://water.nature.org/waterblueprint/#/intro=true", "raw_purpose": "", "raw_constraints_other": "Unless otherwise specified, no restriction applies.", "raw_supplemental_information": "The Urban Water Blueprint analyzes the state of water in more than 2000 watersheds and 530 cities worldwide to provide science-based recommendations for natural solutions that can be integrated alongside traditional infrastructure to improve water quality. The Urban Water Blueprint has continued to improve its scientific analysis over time, correcting reported errors and improving its methodology", "raw_data_quality_statement": "Updated results are not reflected in the report or website. Anyone considering using the results for analysis or decision-making should contact the Urban Water Blueprint at water@tnc.org to obtain the most current estimates.", "metadata_only": false, "thumbnail_url": "http://ihp-wins.unesco.org/uploaded/thumbs/layer-d9c0ebda-46f5-11e8-a93b-005056062634-thumb.png?v=fd2f4974" }, { "pk": "337", "uuid": "60154b1a-e719-11e6-8719-005056bf7531", "resource_type": "layer", "polymorphic_ctype_id": "51", "owner": { "pk": 3, "username": "Tales.Carvalho-Resende", "first_name": "Tales", "last_name": "Carvalho Resende", "avatar": "/static/avatars/Tales.Carvalho-Resende/resized/240/Photo_TalesCarvalhoResende.2b1b88521f4c.jpg" }, "poc": { "pk": 3, "username": "Tales.Carvalho-Resende", "first_name": "Tales", "last_name": "Carvalho Resende", "avatar": "/static/avatars/Tales.Carvalho-Resende/resized/240/Photo_TalesCarvalhoResende.2b1b88521f4c.jpg" }, "metadata_author": { "pk": 3, "username": "Tales.Carvalho-Resende", "first_name": "Tales", "last_name": "Carvalho Resende", "avatar": "/static/avatars/Tales.Carvalho-Resende/resized/240/Photo_TalesCarvalhoResende.2b1b88521f4c.jpg" }, "keywords": [ { "name": "Groundwater", "slug": "groundwater" }, { "name": "Supply", "slug": "Supply" }, { "name": "Transboundary", "slug": "transboundary" } ], "regions": [ { "code": "SLV", "name": "El Salvador" }, { "code": "HND", "name": "Honduras" } ], "category": { "identifier": "Groundwater" }, "title": "Boreholes in the Ocotepeque-Citala Aquifer", "abstract": "This map provides information (water quality, water level, etc...) of boreholes, dug wells, springs and surface water intake points in the transboundary Ocotepeque-Citala Aquifer.", "attribution": null, "doi": null, "alternate": "geonode:ocotepeque_citala_boreholes_v1", "bbox_polygon": { "type": "Polygon", "coordinates": [ [ [ -89.30340659, 14.27296542 ], [ -89.30340659, 14.54075203 ], [ -89.08798283, 14.54075203 ], [ -89.08798283, 14.27296542 ], [ -89.30340659, 14.27296542 ] ] ] }, "ll_bbox_polygon": null, "srid": "EPSG:4326", "date": "2017-01-29T23:00:00Z", "date_type": "publication", "edition": "UNESCO-IHP, 2017", "purpose": "", "maintenance_frequency": null, "restriction_code_type": null, "constraints_other": "Unless otherwise specified, no restriction applies.\r\n", "license": { "identifier": "not_specified" }, "language": "eng", "spatial_representation_type": null, "temporal_extent_start": null, "temporal_extent_end": null, "supplemental_information": "Data was collected within the framework of the Governance of Groundwater Resources in Transboundary Aquifers (GGRETA) project funded by the Swiss Agency for Development and Cooperation (SDC) and executed by UNESCO-IHP.", "data_quality_statement": "/", "group": { "pk": 70, "name": "IHP-Theme2-Groundwater" }, "popular_count": "809", "share_count": "0", "rating": "0", "featured": false, "is_published": true, "is_approved": true, "detail_url": "/layers/ocotepeque_citala_boreholes_v1:geonode:ocotepeque_citala_boreholes_v1", "embed_url": "/layers/geonode:ocotepeque_citala_boreholes_v1/embed", "created": "2020-02-11T11:06:45.204622Z", "last_updated": "2021-02-19T14:30:12.860444Z", "raw_abstract": "This map provides information (water quality, water level, etc...) of boreholes, dug wells, springs and surface water intake points in the transboundary Ocotepeque-Citala Aquifer.", "raw_purpose": "", "raw_constraints_other": "Unless otherwise specified, no restriction applies.", "raw_supplemental_information": "Data was collected within the framework of the Governance of Groundwater Resources in Transboundary Aquifers (GGRETA) project funded by the Swiss Agency for Development and Cooperation (SDC) and executed by UNESCO-IHP.", "raw_data_quality_statement": "/", "metadata_only": false, "thumbnail_url": "http://ihp-wins.unesco.org/uploaded/thumbs/layer-60154b1a-e719-11e6-8719-005056bf7531-thumb.png?v=e93cd328" }, { "pk": "380", "uuid": "22740a30-f38a-11e6-8719-005056bf7531", "resource_type": "layer", 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Hannover: BGR/UNESCO", "purpose": "", "maintenance_frequency": null, "restriction_code_type": null, "constraints_other": "Unless otherwise specified, no restriction applies.", "license": { "identifier": "not_specified" }, "language": "eng", "spatial_representation_type": null, "temporal_extent_start": null, "temporal_extent_end": null, "supplemental_information": "No information provided", "data_quality_statement": "/", "group": { "pk": 70, "name": "IHP-Theme2-Groundwater" }, "popular_count": "755", "share_count": "0", "rating": "0", "featured": false, "is_published": true, "is_approved": true, "detail_url": "/layers/river_lake_basins:geonode:river_lake_basins", "embed_url": "/layers/geonode:river_lake_basins/embed", "created": "2020-02-11T11:06:45.204622Z", "last_updated": "2021-02-19T14:30:12.956162Z", "raw_abstract": "The dataset comprises the GIS layer of 405 major river and lake basins of the world. 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Los indicadores de Gestión Territorial de la Región Trifinio buscan medir los impactos de las acciones llevadas a cabo por los programas y proyectos ejecutados por los gobiernos municipales, instituciones públicas, instituciones no gubernamentales, mancomunidades, asociaciones de municipios y organismos de cooperación internacional que interviene en la Región Trifinio de El Salvador, Guatemala y Honduras. Se tomaron en consideración los indicadores relacionados con el Capital Social, el Capital Físico y el Capital Natural a nivel municipal, cuando el municipio hace parte de la región Trifinio, definida por el proyecto GGRETA. \r\nSe tomó un valor que abarca el periodo de (2010 a 2017) (media, valor más elevado según los datos analizados). 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Los indicadores de Gestión Territorial de la Región Trifinio buscan medir los impactos de las acciones llevadas a cabo por los programas y proyectos ejecutados por los gobiernos municipales, instituciones públicas, instituciones no gubernamentales, mancomunidades, asociaciones de municipios y organismos de cooperación internacional que interviene en la Región Trifinio de El Salvador, Guatemala y Honduras. Se tomaron en consideración los indicadores relacionados con el Capital Social, el Capital Físico y el Capital Natural a nivel municipal, cuando el municipio hace parte de la región Trifinio, definida por el proyecto GGRETA. Se tomó un valor que abarca el periodo de (2010 a 2017) (media, valor más elevado según los datos analizados). 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Higher values indicate areas more capable of buffering variations in water supply (i.e. droughts and floods) because they have more water storage capacity upstream.", "attribution": null, "doi": null, "alternate": "geonode:aqueduct_global_upstream_storage", "bbox_polygon": { "type": "Polygon", "coordinates": [ [ [ -179.99900834271713, -55.907841860778376 ], [ -179.99900834271713, 83.63432689118486 ], [ 179.99999999986983, 83.63432689118486 ], [ 179.99999999986983, -55.907841860778376 ], [ -179.99900834271713, -55.907841860778376 ] ] ] }, "ll_bbox_polygon": null, "srid": "EPSG:4326", "date": "2017-01-29T23:00:00Z", "date_type": "publication", "edition": "Gassert, F., M. Landis, M. Luck, P. Reig, and T. Shiao. 2014. “Aqueduct Global Maps 2.1.” Working Paper. Washington, DC: World Resources Institute. 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Aqueduct Global Maps 2.1 include indicators of water quantity, water variability, water quality, public awareness of water issues, access to water, and ecosystem vulnerability.\r\n\r\nFor more information, visit: www.wri.org/publication/aqueduct-global-maps-21", "data_quality_statement": "/", "group": { "pk": 74, "name": "IHP-Theme6-Water-education" }, "popular_count": "266", "share_count": "0", "rating": "0", "featured": false, "is_published": true, "is_approved": true, "detail_url": "/layers/aqueduct_global_upstream_storage:geonode:aqueduct_global_upstream_storage", "embed_url": "/layers/geonode:aqueduct_global_upstream_storage/embed", "created": "2020-02-11T11:06:45.204622Z", "last_updated": "2021-02-19T14:30:12.700396Z", "raw_abstract": "Upstream storage measures the water storage capacity available upstream of a location relative to the total water supply at that location from 1950 to 2010. 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Many cities rely partially or totally on surface water sources. The study of the Natural Conservancy focus on the analysis of surface water quality and quantity. This footprint analysis involve 534 cities, who draw water from 20 percent of the world’s land surface.\r\nFor more information, access the Urban Water Blueprint report here: http://www.iwa-network.org/wp-content/uploads/2016/06/Urban-Water-Blueprint-Report.pdf\r\nYou can also visit the Urban Water Blueprint website here: http://water.nature.org/waterblueprint/#/intro=true", "attribution": null, "doi": null, "alternate": "geonode:surface_nc", "bbox_polygon": { "type": "Polygon", "coordinates": [ [ [ -149.8921253, -43.52765168 ], [ -149.8921253, 61.21766954 ], [ 174.7646444, 61.21766954 ], [ 174.7646444, -43.52765168 ], [ -149.8921253, -43.52765168 ] ] ] }, "ll_bbox_polygon": null, "srid": "EPSG:4326", "date": "2018-06-20T15:06:00Z", "date_type": "publication", "edition": "McDonald, R.I. & D. Shemie (2014). 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Anyone considering using the results for analysis or decision-making should contact the Urban Water Blueprint at water@tnc.org to obtain the most current estimates.", "group": { "pk": 72, "name": "IHP-Theme4-Water-for-settlements" }, "popular_count": "122", "share_count": "0", "rating": "0", "featured": true, "is_published": true, "is_approved": true, "detail_url": "/layers/geonode_ihp_data:geonode:surface_nc", "embed_url": "/layers/geonode:surface_nc/embed", "created": "2020-02-11T11:06:45.204622Z", "last_updated": "2021-02-19T14:30:13.493060Z", "raw_abstract": "Today, cities are looking farther beyond their limits for clean water. Many cities rely partially or totally on surface water sources. The study of the Natural Conservancy focus on the analysis of surface water quality and quantity. This footprint analysis involve 534 cities, who draw water from 20 percent of the world’s land surface. For more information, access the Urban Water Blueprint report here: http://www.iwa-network.org/wp-content/uploads/2016/06/Urban-Water-Blueprint-Report.pdf You can also visit the Urban Water Blueprint website here: http://water.nature.org/waterblueprint/#/intro=true", "raw_purpose": "", "raw_constraints_other": "Unless otherwise specified, no restriction applies.", "raw_supplemental_information": "The Urban Water Blueprint analyzes the state of water in more than 2000 watersheds and 530 cities worldwide to provide science-based recommendations for natural solutions that can be integrated alongside traditional infrastructure to improve water quality. The Urban Water Blueprint has continued to improve its scientific analysis over time, correcting reported errors and improving its methodology", "raw_data_quality_statement": "Updated results are not reflected in the report or website. Anyone considering using the results for analysis or decision-making should contact the Urban Water Blueprint at water@tnc.org to obtain the most current estimates.", "metadata_only": false, "thumbnail_url": "http://ihp-wins.unesco.org/uploaded/thumbs/layer-c85fb48c-4300-11e8-a93b-005056062634-thumb.png?v=ecd38f3b" } ] }
