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On April 29, 2021 at 6:52:15 AM UTC, Administrator:

Updated description of Forest canopy structure data for radiation and snow modelling (CH/FIN) from
This dataset contains forest canopy structure data acquired in a spruce forest at Laret, Switzerland, and a pine forest at Sodankylä, Finland. Data include: * Hemispherical photographs taken at transect intersection points of 13 experimental plots (40x40m each) * a Canopy Height Model (tree height map) derived by rasterizing airborne LiDAR data, encompassing the entire simulation domain at Laret (150'000 m2) These data provide the necessary basis for creating canopy structure datasets to be used as input to the forest snow snow model FSM2. These datasets, the model input derivatives and the radiation and snow modelling are described in detail in the following publication: _Mazzotti, G., Webster, C., Essery, R., and Jonas, T. (2021) Improving the physical representation of forest snow processes in coarse-resolution models: lessons learned from upscaling hyper-resolution simulations. Water Resources Research 57, e2020WR029064. [doi: 10.1029/2020WR029064](https://doi.org/10.1029/2020WR029064) This publication must be cited when using the data. ### See also: For additional information on the FSM2 model, see the corresponding [GitHub repository](https://github.com/GiuliaMazzotti/FSM2/tree/hyres_enhanced_canopy) The datasets and the model have also been used in _Mazzotti et al. (2020) Process-level evaluation of a hyper-resolution forest snow model using distributed multi-sensor observations. [doi: 10.1029/2020WR027572](https://doi.org/10.1029/2020WR027572)
to
This dataset contains forest canopy structure data acquired in a spruce forest at Laret, Switzerland, and a pine forest at Sodankylä, Finland. Data include: * Hemispherical photographs taken at transect intersection points of 13 experimental plots (40x40m each) * a Canopy Height Model (tree height map) derived by rasterizing airborne LiDAR data, encompassing the entire simulation domain at Laret (150'000 m2) These data provide the necessary basis for creating canopy structure datasets to be used as input to the forest snow snow model FSM2. These datasets, the model input derivatives and the radiation and snow modelling are described in detail in the following publication: _Mazzotti, G., Webster, C., Essery, R., and Jonas, T. (2021) Improving the physical representation of forest snow processes in coarse-resolution models: lessons learned from upscaling hyper-resolution simulations. Water Resources Research 57, e2020WR029064. [doi: 10.1029/2020WR029064](https://doi.org/10.1029/2020WR029064) _ This publication must be cited when using the data. ### See also: For additional information on the FSM2 model, see the corresponding [GitHub repository](https://github.com/GiuliaMazzotti/FSM2/tree/hyres_enhanced_canopy) The datasets and the model have also been used in _Mazzotti et al. (2020) Process-level evaluation of a hyper-resolution forest snow model using distributed multi-sensor observations. [doi: 10.1029/2020WR027572](https://doi.org/10.1029/2020WR027572)

              
    
          
          
        
        
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            34   "metadata_created": "2020-10-22T19:57:45.319314", 34   "metadata_created": "2020-10-22T19:57:45.319314",
            n 35   "metadata_modified": "2021-04-29T06:51:18.298154", n 35   "metadata_modified": "2021-04-29T06:52:15.057068",
            36   "name": "chm-hp-4rtm", 36   "name": "chm-hp-4rtm",
            37   "notes": "This dataset contains forest canopy structure data  37   "notes": "This dataset contains forest canopy structure data 
            38 acquired in a spruce forest at Laret, Switzerland, and a pine forest  38 acquired in a spruce forest at Laret, Switzerland, and a pine forest 
            39 at Sodankyl\u00e4, Finland. Data include: \r\n\r\n* Hemispherical  39 at Sodankyl\u00e4, Finland. Data include: \r\n\r\n* Hemispherical 
            40 photographs taken at transect intersection points of 13 experimental  40 photographs taken at transect intersection points of 13 experimental 
            41 plots (40x40m each)\r\n* a Canopy Height Model (tree height map)  41 plots (40x40m each)\r\n* a Canopy Height Model (tree height map) 
            42 derived by rasterizing airborne LiDAR data, encompassing the entire  42 derived by rasterizing airborne LiDAR data, encompassing the entire 
            43 simulation domain at Laret (150'000 m2)\r\n\r\n\r\nThese data provide  43 simulation domain at Laret (150'000 m2)\r\n\r\n\r\nThese data provide 
            44 the necessary basis for creating canopy structure datasets to be used  44 the necessary basis for creating canopy structure datasets to be used 
            45 as input to the forest snow snow model FSM2. These datasets, the model  45 as input to the forest snow snow model FSM2. These datasets, the model 
            46 input derivatives and the radiation and snow modelling are described  46 input derivatives and the radiation and snow modelling are described 
            47 in detail in the following publication:\r\n\r\n_Mazzotti, G., Webster,  47 in detail in the following publication:\r\n\r\n_Mazzotti, G., Webster, 
            48 C., Essery, R., and Jonas, T. (2021) Improving the physical  48 C., Essery, R., and Jonas, T. (2021) Improving the physical 
            49 representation of forest snow processes in coarse-resolution models:  49 representation of forest snow processes in coarse-resolution models: 
            50 lessons learned from upscaling hyper-resolution simulations. Water  50 lessons learned from upscaling hyper-resolution simulations. Water 
            51 Resources Research 57, e2020WR029064. [doi:  51 Resources Research 57, e2020WR029064. [doi: 
            t 52 0.1029/2020WR029064](https://doi.org/10.1029/2020WR029064)\r\n\r\nThis  t 52 10.1029/2020WR029064](https://doi.org/10.1029/2020WR029064) 
            53 publication must be cited when using the data. \r\n\r\n### See also:  53 _\r\n\r\nThis publication must be cited when using the data. 
            54 \r\nFor additional information on the FSM2 model, see the  54 \r\n\r\n### See also: \r\nFor additional information on the FSM2 
            55 corresponding [GitHub  55 model, see the corresponding [GitHub 
            56 /github.com/GiuliaMazzotti/FSM2/tree/hyres_enhanced_canopy)\r\n\r\nThe  56 /github.com/GiuliaMazzotti/FSM2/tree/hyres_enhanced_canopy)\r\n\r\nThe 
            57 datasets and the model have also been used in _Mazzotti et al. (2020)  57 datasets and the model have also been used in _Mazzotti et al. (2020) 
            58 Process-level evaluation of a hyper-resolution forest snow model using  58 Process-level evaluation of a hyper-resolution forest snow model using 
            59 distributed multi-sensor observations. [doi:  59 distributed multi-sensor observations. [doi: 
            60 10.1029/2020WR027572](https://doi.org/10.1029/2020WR027572)\r\n\r\n", 60 10.1029/2020WR027572](https://doi.org/10.1029/2020WR027572)\r\n\r\n",
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            67 processes in mountainous areas, in particular the triggering and  67 processes in mountainous areas, in particular the triggering and 
            68 propagation of floods, sediment transport, landslides, debris flows  68 propagation of floods, sediment transport, landslides, debris flows 
            69 and rock fall. Process studies on the scale of slopes, channels and  69 and rock fall. Process studies on the scale of slopes, channels and 
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            75 assessed as prerequisites for the risk-based and sustainable  75 assessed as prerequisites for the risk-based and sustainable 
            76 management of natural hazards.\r\n\r\nA second focus of the unit is on  76 management of natural hazards.\r\n\r\nA second focus of the unit is on 
            77 the estimation and prediction of snow and water resources, e.g. for  77 the estimation and prediction of snow and water resources, e.g. for 
            78 hydropower production or early recognition of drought. The unit  78 hydropower production or early recognition of drought. The unit 
            79 operates a snow hydrological service for federal and cantonal agencies  79 operates a snow hydrological service for federal and cantonal agencies 
            80 and a drought information platform for a broad range of water  80 and a drought information platform for a broad range of water 
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            94 \"EnviDat\"}", 94 \"EnviDat\"}",
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            96   "related_datasets": "", 96   "related_datasets": "",
            97   "related_publications": "Mazzotti, G., Webster, C., Essery, R., and  97   "related_publications": "Mazzotti, G., Webster, C., Essery, R., and 
            98 Jonas, T. (2021) Improving the physical representation of forest snow  98 Jonas, T. (2021) Improving the physical representation of forest snow 
            99 processes in coarse-resolution models: lessons learned from upscaling  99 processes in coarse-resolution models: lessons learned from upscaling 
            100 hyper-resolution simulations. Water Resources Research 57,  100 hyper-resolution simulations. Water Resources Research 57, 
            101 e2020WR029064. [doi:  101 e2020WR029064. [doi: 
            102 10.1029/2020WR029064](https://doi.org/10.1029/2020WR029064)", 102 10.1029/2020WR029064](https://doi.org/10.1029/2020WR029064)",
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            165   "spatial": "{\"type\":\"MultiPoint\",\"coordinates\":[[9.871859,  165   "spatial": "{\"type\":\"MultiPoint\",\"coordinates\":[[9.871859, 
            166 46.845432],[26.63658857345581,67.36682702851057]]}", 166 46.845432],[26.63658857345581,67.36682702851057]]}",
            167   "spatial_info": "Switzerland, Finland", 167   "spatial_info": "Switzerland, Finland",
            168   "state": "active", 168   "state": "active",
            169   "subtitle": "", 169   "subtitle": "",
            170   "tags": [ 170   "tags": [
            171     { 171     {
            172       "display_name": "ENERGY BALANCE", 172       "display_name": "ENERGY BALANCE",
            173       "id": "b1503a80-568e-4f95-b638-7267bc12cc0a", 173       "id": "b1503a80-568e-4f95-b638-7267bc12cc0a",
            174       "name": "ENERGY BALANCE", 174       "name": "ENERGY BALANCE",
            175       "state": "active", 175       "state": "active",
            176       "vocabulary_id": null 176       "vocabulary_id": null
            177     }, 177     },
            178     { 178     {
            179       "display_name": "FOREST CANOPY", 179       "display_name": "FOREST CANOPY",
            180       "id": "e09c7bc3-8d21-4a36-8bd0-0c222dd74e7b", 180       "id": "e09c7bc3-8d21-4a36-8bd0-0c222dd74e7b",
            181       "name": "FOREST CANOPY", 181       "name": "FOREST CANOPY",
            182       "state": "active", 182       "state": "active",
            183       "vocabulary_id": null 183       "vocabulary_id": null
            184     }, 184     },
            185     { 185     {
            186       "display_name": "MASS BALANCE", 186       "display_name": "MASS BALANCE",
            187       "id": "3a7f131c-08f0-430b-874f-1165ac70bbfa", 187       "id": "3a7f131c-08f0-430b-874f-1165ac70bbfa",
            188       "name": "MASS BALANCE", 188       "name": "MASS BALANCE",
            189       "state": "active", 189       "state": "active",
            190       "vocabulary_id": null 190       "vocabulary_id": null
            191     }, 191     },
            192     { 192     {
            193       "display_name": "SNOW MODELLING", 193       "display_name": "SNOW MODELLING",
            194       "id": "ac0cab5d-dbcb-47da-bf2b-412714fd87ec", 194       "id": "ac0cab5d-dbcb-47da-bf2b-412714fd87ec",
            195       "name": "SNOW MODELLING", 195       "name": "SNOW MODELLING",
            196       "state": "active", 196       "state": "active",
            197       "vocabulary_id": null 197       "vocabulary_id": null
            198     }, 198     },
            199     { 199     {
            200       "display_name": "UPSCALING", 200       "display_name": "UPSCALING",
            201       "id": "fd5090a2-303f-4860-8d2e-de26f8f230de", 201       "id": "fd5090a2-303f-4860-8d2e-de26f8f230de",
            202       "name": "UPSCALING", 202       "name": "UPSCALING",
            203       "state": "active", 203       "state": "active",
            204       "vocabulary_id": null 204       "vocabulary_id": null
            205     } 205     }
            206   ], 206   ],
            207   "title": "Forest canopy structure data for radiation and snow  207   "title": "Forest canopy structure data for radiation and snow 
            208 modelling (CH/FIN)", 208 modelling (CH/FIN)",
            209   "type": "dataset", 209   "type": "dataset",
            210   "url": null, 210   "url": null,
            211   "version": "1.0" 211   "version": "1.0"
            212 } 212 }