Example #1
0
        public void EvaporateTest()
        {
            IsotopeWater Iw = new IsotopeWater(100);

            Iw.SetIsotopeRatio(10);
            TimestampSeries ts = new TimestampSeries();

            ts.AddSiValue(new DateTime(2000, 1, 1), 5);
            ts.AllowExtrapolation       = true;
            ts.ExtrapolationMethod      = ExtrapolationMethods.Linear;
            ts.RelaxationFactor         = 1;
            Iw.EvaporationConcentration = ts;

            Iw.Evaporate(1);
            double v1 = Iw.GetIsotopeRatio();

            Iw.Evaporate(2);
            double v2 = Iw.GetIsotopeRatio();

            Iw.Evaporate(5);
            double v5 = Iw.GetIsotopeRatio();

            Iw.Evaporate(90);
            double v90 = Iw.GetIsotopeRatio();

            Assert.AreEqual(10.101, v1, 0.01);
            Assert.AreEqual(10.309, v2, 0.01);
            Assert.AreEqual(10.870, v5, 0.01);
            Assert.AreEqual(500, Iw.GetIsotopeRatio(), 0.01);
        }
Example #2
0
        public void IsotopeTest()
        {
            DateTime Start = new DateTime(2007, 1, 1);
            DateTime End   = new DateTime(2007, 12, 31);

            Model m       = ModelFactory.GetModel(testDataPath + "VedstedNoGroundwater.xml");
            Lake  Vedsted = (Lake)m._waterBodies[0];

            Vedsted.Sources.RemoveAt(0);

            Chemical cl = ChemicalFactory.Instance.GetChemical(ChemicalNames.Cl);

            Vedsted.Output.LogChemicalConcentration(ChemicalFactory.Instance.GetChemical(ChemicalNames.IsotopeFraction));
            Vedsted.Output.LogChemicalConcentration(cl);

            IsotopeWater Iw = new IsotopeWater(1);

            Iw.SetIsotopeRatio(10);
            Iw.AddChemical(cl, 0.1);

            Assert.AreEqual(10, Iw.GetConcentration(ChemicalFactory.Instance.GetChemical(ChemicalNames.IsotopeFraction)));
            m.SetState("Initial", Start, Iw);

            Assert.AreEqual(10, ((WaterPacket)Vedsted.CurrentStoredWater).GetConcentration(ChemicalFactory.Instance.GetChemical(ChemicalNames.IsotopeFraction)));

            IsotopeWater precip = new IsotopeWater(1);

            precip.SetIsotopeRatio(5);
            m.MoveInTime(End, TimeSpan.FromDays(30));

            foreach (var v in Vedsted.Output.Items[6].Values)
            {
                Console.WriteLine(v);
            }
            foreach (var v in Vedsted.Output.Items[5].Values)
            {
                Console.WriteLine(v);
            }

            Console.WriteLine(Vedsted.Output.GetStorageTime(Start.AddDays(40), End.AddDays(-40)));

            ModelFactory.SaveModel(testDataPath + "VedstedIso.xml", m);
        }
Example #3
0
        public void CastingTest()
        {
            IsotopeWater Iw = new IsotopeWater(100);

            Iw.SetIsotopeRatio(0.5);

            Assert.IsFalse(Iw.GetType().Equals(typeof(WaterPacket)));

            WaterPacket wc = Iw as WaterPacket;

            Assert.IsNotNull(wc);

            Assert.IsTrue(wc.Chemicals.ContainsKey(ChemicalFactory.Instance.GetChemical(ChemicalNames.IsotopeFraction)));

            WaterPacket w = new WaterPacket(1);

            wc = w as IsotopeWater;
            Assert.IsNull(wc);
        }
Example #4
0
        public void KrabbenhoftExample()
        {
            Lake L = new Lake("Sparkling Lake", XYPolygon.GetSquare(0.81e6));

            L.Depth = 8.84e6 / L.Area;
            L.Output.LogAllChemicals = true;

            IsotopeWater LakeWater = new IsotopeWater(1);

            LakeWater.SetIsotopeRatio(5.75);
            TimestampSeries EvapoConcentrations = new TimestampSeries();

            EvapoConcentrations.AddSiValue(new DateTime(1985, 4, 1), 3.95);
            EvapoConcentrations.AddSiValue(new DateTime(1985, 5, 1), 13.9);
            EvapoConcentrations.AddSiValue(new DateTime(1985, 6, 1), 25.24);
            EvapoConcentrations.AddSiValue(new DateTime(1985, 7, 1), 23.97);
            EvapoConcentrations.AddSiValue(new DateTime(1985, 8, 1), 17.13);
            EvapoConcentrations.AddSiValue(new DateTime(1985, 9, 1), 10.40);
            EvapoConcentrations.AddSiValue(new DateTime(1985, 10, 1), 6.12);
            EvapoConcentrations.AddSiValue(new DateTime(1985, 10, 1), 33.24);
            EvapoConcentrations.AllowExtrapolation  = true;
            EvapoConcentrations.ExtrapolationMethod = ExtrapolationMethods.RecycleYear;
            LakeWater.EvaporationConcentration      = EvapoConcentrations;

            TimestampSeries PrecipConcentrations = new TimestampSeries();

            PrecipConcentrations.AddSiValue(new DateTime(1985, 1, 1), 22.8);
            PrecipConcentrations.AddSiValue(new DateTime(1985, 2, 1), 22.8);
            PrecipConcentrations.AddSiValue(new DateTime(1985, 3, 1), 22.8);
            PrecipConcentrations.AddSiValue(new DateTime(1985, 4, 1), 14.8);
            PrecipConcentrations.AddSiValue(new DateTime(1985, 5, 1), 10.7);
            PrecipConcentrations.AddSiValue(new DateTime(1985, 6, 1), 6.3);
            PrecipConcentrations.AddSiValue(new DateTime(1985, 7, 1), 5.1);
            PrecipConcentrations.AddSiValue(new DateTime(1985, 8, 1), 8.4);
            PrecipConcentrations.AddSiValue(new DateTime(1985, 9, 1), 11.1);
            PrecipConcentrations.AddSiValue(new DateTime(1985, 10, 1), 13.8);
            PrecipConcentrations.AddSiValue(new DateTime(1985, 10, 1), 21.9);
            PrecipConcentrations.AllowExtrapolation  = true;
            PrecipConcentrations.ExtrapolationMethod = ExtrapolationMethods.RecycleYear;

            TimespanSeries Precipitation = new TimespanSeries();

            Precipitation.Unit = new HydroNumerics.Core.Unit("cm/month", 1.0 / 100.0 / (86400.0 * 30.0), 0);
            Precipitation.AddValue(new DateTime(1985, 1, 1), new DateTime(1985, 3, 1), 0);
            Precipitation.AddValue(new DateTime(1985, 3, 1), new DateTime(1985, 3, 31), 12.5);
            Precipitation.AddValue(new DateTime(1985, 4, 1), new DateTime(1985, 4, 30), 7.1);
            Precipitation.AddValue(new DateTime(1985, 5, 1), new DateTime(1985, 5, 31), 7.6);
            Precipitation.AddValue(new DateTime(1985, 6, 1), new DateTime(1985, 6, 30), 8.8);
            Precipitation.AddValue(new DateTime(1985, 7, 1), new DateTime(1985, 7, 31), 8.6);
            Precipitation.AddValue(new DateTime(1985, 8, 1), new DateTime(1985, 8, 31), 12.7);
            Precipitation.AddValue(new DateTime(1985, 9, 1), new DateTime(1985, 9, 30), 11);
            Precipitation.AddValue(new DateTime(1985, 10, 1), new DateTime(1985, 10, 31), 6.2);
            Precipitation.AddValue(new DateTime(1985, 11, 1), new DateTime(1985, 11, 30), 4.8);
            Precipitation.AddValue(new DateTime(1985, 11, 30), new DateTime(1985, 12, 31), 0);
            Precipitation.AllowExtrapolation  = true;
            Precipitation.ExtrapolationMethod = ExtrapolationMethods.RecycleYear;

            Assert.AreEqual(79, 12 * Precipitation.GetValue(new DateTime(1985, 1, 1), new DateTime(1985, 12, 31)), 3);

            SourceBoundary Precip = new SourceBoundary(Precipitation);

            Precip.WaterSample = new IsotopeWater(1);
            Precip.AddChemicalConcentrationSeries(ChemicalFactory.Instance.GetChemical(ChemicalNames.IsotopeFraction), PrecipConcentrations);

            TimespanSeries Evaporation = new TimespanSeries();

            Evaporation.Unit = new HydroNumerics.Core.Unit("cm/month", 1.0 / 100.0 / (86400.0 * 30.0), 0);
            Evaporation.AddValue(new DateTime(1985, 1, 1), new DateTime(1985, 4, 1), 0);
            Evaporation.AddValue(new DateTime(1985, 4, 1), new DateTime(1985, 4, 30), 2.8);
            Evaporation.AddValue(new DateTime(1985, 5, 1), new DateTime(1985, 5, 31), 7.0);
            Evaporation.AddValue(new DateTime(1985, 6, 1), new DateTime(1985, 6, 30), 10.5);
            Evaporation.AddValue(new DateTime(1985, 7, 1), new DateTime(1985, 7, 31), 11.1);
            Evaporation.AddValue(new DateTime(1985, 8, 1), new DateTime(1985, 8, 31), 10.0);
            Evaporation.AddValue(new DateTime(1985, 9, 1), new DateTime(1985, 9, 30), 7.0);
            Evaporation.AddValue(new DateTime(1985, 10, 1), new DateTime(1985, 10, 31), 4.7);
            Evaporation.AddValue(new DateTime(1985, 11, 1), new DateTime(1985, 11, 30), 0.6);
            Evaporation.AddValue(new DateTime(1985, 11, 30), new DateTime(1985, 12, 31), 0);
            Evaporation.AllowExtrapolation  = true;
            Evaporation.ExtrapolationMethod = ExtrapolationMethods.RecycleYear;
            EvaporationRateBoundary erb = new EvaporationRateBoundary(Evaporation);

            Assert.AreEqual(54, 12 * Evaporation.GetValue(new DateTime(1985, 1, 1), new DateTime(1985, 12, 31)), 3);


            GroundWaterBoundary grb = new GroundWaterBoundary(L, 1e-7, 1, 1, (XYPolygon)L.Geometry);

            grb.FlowType  = GWType.Flow;
            grb.WaterFlow = new TimespanSeries();
            grb.WaterFlow.AddSiValue(DateTime.MinValue, DateTime.MaxValue, Evaporation.Unit.ToSiUnit(29 / 12) * L.Area);
            IsotopeWater gwsp25 = new IsotopeWater(1);

            gwsp25.SetIsotopeRatio(11.5);
            grb.WaterSample = gwsp25;

            GroundWaterBoundary gout = new GroundWaterBoundary(L, 1e-7, 1, -1, (XYPolygon)L.Geometry);

            gout.FlowType  = GWType.Flow;
            gout.WaterFlow = new TimespanSeries();
            gout.WaterFlow.AddSiValue(DateTime.MinValue, DateTime.MaxValue, -Evaporation.Unit.ToSiUnit(54 / 12) * L.Area);

            DateTime Start = new DateTime(1985, 1, 1);

            L.Precipitation.Add(Precip);
            Precip.ContactGeometry = L.Geometry;
            L.EvaporationBoundaries.Add(erb);
            erb.ContactGeometry = L.Geometry;
            L.GroundwaterBoundaries.Add(grb);
            L.GroundwaterBoundaries.Add(gout);

            Model M = new Model();

            M.WaterBodies.Add(L);
            M.SetState("Initial", Start, LakeWater);

            L.Depth *= 1.5;
            ((IsotopeWater)L.CurrentStoredWater).CurrentTime = Start;
            M.MoveInTime(new DateTime(1985, 12, 31), TimeSpan.FromDays(10));

            M.Save(@"..\..\..\TestData\Krabbenhoft.xml");
        }
Example #5
0
    public void IsotopeTest()
    {
      DateTime Start = new DateTime(2007, 1, 1);
      DateTime End = new DateTime(2007, 12, 31);

      Model m = ModelFactory.GetModel(testDataPath + "VedstedNoGroundwater.xml");
      Lake Vedsted = (Lake)m._waterBodies[0];
      Vedsted.Sources.RemoveAt(0);

      Chemical cl = ChemicalFactory.Instance.GetChemical(ChemicalNames.Cl);
      Vedsted.Output.LogChemicalConcentration(ChemicalFactory.Instance.GetChemical(ChemicalNames.IsotopeFraction));
      Vedsted.Output.LogChemicalConcentration(cl);

      IsotopeWater Iw = new IsotopeWater(1);
      Iw.SetIsotopeRatio(10);
      Iw.AddChemical(cl, 0.1);

      Assert.AreEqual(10,Iw.GetConcentration(ChemicalFactory.Instance.GetChemical(ChemicalNames.IsotopeFraction)));
       m.SetState("Initial", Start, Iw);

       Assert.AreEqual(10, ((WaterPacket)Vedsted.CurrentStoredWater).GetConcentration(ChemicalFactory.Instance.GetChemical(ChemicalNames.IsotopeFraction)));

       IsotopeWater precip = new IsotopeWater(1);
       precip.SetIsotopeRatio(5);
      m.MoveInTime(End, TimeSpan.FromDays(30));

      foreach (var v in Vedsted.Output.Items[6].Values)
        Console.WriteLine(v);
      foreach (var v in Vedsted.Output.Items[5].Values)
        Console.WriteLine(v);

      Console.WriteLine(Vedsted.Output.GetStorageTime(Start.AddDays(40), End.AddDays(-40)));

      ModelFactory.SaveModel(testDataPath + "VedstedIso.xml",m);
    }
        public void TestMethod1()
        {
            Lake Vedsted = LakeFactory.GetLake("Vedsted Sø");

            Vedsted.Depth      = 5;
            Vedsted.WaterLevel = 45.7;


            //Create and add precipitation boundary
            TimespanSeries Precipitation = new TimespanSeries();

            double[] values = new double[] { 108, 83, 73, 52, 61, 86, 99, 101, 75, 108, 85, 101 };
            LakeVedsted.AddMonthlyValues(Precipitation, 2007, values);
            SinkSourceBoundary Precip = new SinkSourceBoundary(Precipitation);

            Precip.ContactGeometry = Vedsted.SurfaceArea;
            Vedsted.Sources.Add(Precip);

            //Create and add evaporation boundary
            TimespanSeries Evaporation = new TimespanSeries();

            double[] values2 = new double[] { 4, 11, 34, 66, 110, 118, 122, 103, 61, 26, 7, 1 };
            LakeVedsted.AddMonthlyValues(Evaporation, 2007, values2);
            EvaporationRateBoundary eva = new EvaporationRateBoundary(Evaporation);

            eva.ContactGeometry = Vedsted.SurfaceArea;
            Vedsted.EvaporationBoundaries.Add(eva);

            //Create and add a discharge boundary
            TimestampSeries Discharge = new TimestampSeries();

            Discharge.AddSiValue(new DateTime(2007, 3, 12), 6986 / TimeSpan.FromDays(365).TotalSeconds);
            Discharge.AddSiValue(new DateTime(2007, 4, 3), 5894 / TimeSpan.FromDays(365).TotalSeconds);
            Discharge.AddSiValue(new DateTime(2007, 4, 25), 1205 / TimeSpan.FromDays(365).TotalSeconds);
            Discharge.RelaxationFactor   = 1;
            Discharge.AllowExtrapolation = true;
            Assert.AreEqual(Discharge.GetValue(new DateTime(2007, 4, 25)), Discharge.GetValue(new DateTime(2007, 6, 25)), 0.0000001);
            SinkSourceBoundary Kilde = new SinkSourceBoundary(Discharge);

            Vedsted.Sources.Add(Kilde);

            //Add a groundwater boundary
            GroundWaterBoundary gwb = new GroundWaterBoundary(Vedsted, 1e-5, 1, 46, (XYPolygon)Vedsted.Geometry);

            DateTime Start = new DateTime(2007, 1, 1);

            //Add the chemicals
            Chemical cl = ChemicalFactory.Instance.GetChemical(ChemicalNames.Cl);

            //Tell the lake to log the chemicals
            Vedsted.Output.LogChemicalConcentration(ChemicalFactory.Instance.GetChemical(ChemicalNames.IsotopeFraction));
            Vedsted.Output.LogChemicalConcentration(cl);

            IsotopeWater Iw = new IsotopeWater(1);

            Iw.SetIsotopeRatio(10);
            Iw.AddChemical(cl, 0.1);
            Precip.WaterSample = Iw.DeepClone();

            //Evaporate some of the water to get realistic initial conditions
            Iw.Evaporate(Iw.Volume / 2);
            Vedsted.SetState("Initial", Start, Iw.DeepClone());
            Kilde.WaterSample = Iw.DeepClone();

            Iw.Evaporate(Iw.Volume / 2);
            gwb.WaterSample = Iw.DeepClone();

            //Add to an engine
            Model Engine = new Model();

            Engine.Name = "Vedsted-opsætning";
            Engine._waterBodies.Add(Vedsted);

            //Set initial state
            Engine.SetState("Initial", Start, new WaterPacket(1));

            Engine.Save(@"c:\temp\setup.xml");
        }
Example #7
0
        public DemoViewModel(string Name, XYPolygon SurfaceArea, TimespanSeries Evaporation, TimespanSeries Precipitation)
        {
            Calibration      = 1;
            _lake            = new Lake(Name, SurfaceArea);
            _lake.Depth      = 5;
            _lake.WaterLevel = 45.7;

            //Create and add precipitation boundary
            SinkSourceBoundary Precip = new SinkSourceBoundary(Precipitation);

            Precip.ContactGeometry = _lake.SurfaceArea;
            _lake.Sources.Add(Precip);

            //Create and add evaporation boundary
            EvaporationRateBoundary eva = new EvaporationRateBoundary(Evaporation);

            eva.ContactGeometry = _lake.SurfaceArea;
            _lake.EvaporationBoundaries.Add(eva);

            //Create and add a discharge boundary
            Discharge = new TimestampSeries();
            Discharge.AddSiValue(new DateTime(2007, 3, 12), 6986 / TimeSpan.FromDays(365).TotalSeconds);
            Discharge.AddSiValue(new DateTime(2007, 4, 3), 5894 / TimeSpan.FromDays(365).TotalSeconds);
            Discharge.AddSiValue(new DateTime(2007, 4, 25), 1205 / TimeSpan.FromDays(365).TotalSeconds);
            Discharge.RelaxationFactor   = 1;
            Discharge.AllowExtrapolation = true;
            Discharge.Name = "Inflow";
            SinkSourceBoundary Kilde = new SinkSourceBoundary(Discharge);

            _lake.Sources.Add(Kilde);

            //Add a groundwater boundary
            GroundWaterBoundary gwb = new GroundWaterBoundary(_lake, 1e-7, 1, 46, (XYPolygon)_lake.Geometry);

            _lake.GroundwaterBoundaries.Add(gwb);

            DateTime Start = new DateTime(2007, 1, 1);

            //Add to an engine
            Engine = new Model();
            Engine._waterBodies.Add(_lake);

            //Set initial state
            Engine.SetState("Initial", Start, new WaterPacket(1));

            //Add the chemicals
            Chemical cl = ChemicalFactory.Instance.GetChemical(ChemicalNames.Cl);

            //Tell the lake to log the chemicals
            _lake.Output.LogChemicalConcentration(ChemicalFactory.Instance.GetChemical(ChemicalNames.IsotopeFraction));
            _lake.Output.LogChemicalConcentration(cl);

            IsotopeWater Iw = new IsotopeWater(1);

            Iw.SetIsotopeRatio(0.2);
            Iw.AddChemical(cl, 0.1);
            Precip.WaterSample = Iw.DeepClone();

            //Evaporate some of the water to get realistic initial conditions
            Iw.Evaporate(Iw.Volume / 2);
            _lake.SetState("Initial", Start, Iw.DeepClone(_lake.Volume));
            Kilde.WaterSample = Iw.DeepClone();

            Iw.Evaporate(Iw.Volume / 2);
            gwb.WaterSample = Iw.DeepClone();
        }