public void RoutingOfInflow() { Stream S = new Stream("S", 10, 1, 1); DateTime Start = DateTime.Now; S.SetState("Initial", Start, new WaterPacket(1, 10)); Stream s2 = new Stream("s2", 10, 1, 1); Lake Storage = new Lake("storage", 100000); S.AddDownStreamWaterBody(s2); s2.AddDownStreamWaterBody(Storage); SinkSourceBoundary FB = new SinkSourceBoundary(5.0 / 60); FB.WaterSample = new WaterPacket(5, 5); S.Sources.Add(FB); TimeSpan ts = new TimeSpan(0, 1, 0); WaterPacket WaterProvider = new WaterPacket(2, 5); S.AddWaterPacket(Start, Start.AddDays(1), WaterProvider.DeepClone(15)); S.Update(S.CurrentTime.Add(ts)); s2.Update(S.CurrentTime.Add(ts)); Assert.AreEqual(10, S.CurrentStoredWater.Volume, 0.00001); Assert.AreEqual(0.137, S.CurrentStoredWater.Composition[5], 0.001); Assert.AreEqual(0.863, S.CurrentStoredWater.Composition[2], 0.001); Assert.AreEqual(0.1309, s2.CurrentStoredWater.Composition[1], 0.001); }
public void RoutingOfInflow2() { Stream S = new Stream("S", 25, 1, 1); DateTime Start = DateTime.Now; S.SetState("Initial", Start, new WaterPacket(1, 25)); Stream s2 = new Stream("s2", 50, 1, 1); s2.SetState("Initial", Start, new WaterPacket(50)); Stream s3 = new Stream("s3", 300, 1, 1); s3.SetState("Initial", Start, new WaterPacket(300)); S.AddDownStreamWaterBody(s2); s2.AddDownStreamWaterBody(s3); SinkSourceBoundary FB = new SinkSourceBoundary(0.0005); FB.WaterSample = new WaterPacket(5, 5); S.Sources.Add(FB); TimeSpan ts = new TimeSpan(1, 0, 0); WaterPacket WaterProvider = new WaterPacket(2, 200); S.AddWaterPacket(DateTime.Now, DateTime.Now, WaterProvider.DeepClone(200)); S.Update(S.CurrentTime.Add(ts)); }
public void OutputTest() { TimeSpan ts = new TimeSpan(0, 1, 0); Stream S = new Stream("S", 10, 1, 1); S.SetState("Initial", DateTime.Now, new WaterPacket(1, 10)); for (int i = 0; i < 10; i++) { S.AddWaterPacket(DateTime.Now, DateTime.Now.AddDays(1), new WaterPacket(25 * i)); S.Update(S.CurrentTime.Add(ts)); } for (int i = 0; i < 10; i++) { Assert.AreEqual(i * 25.0 / ts.TotalSeconds, S.Output.Outflow.Items[i].Value); } }
public void RoutingOfGroundwaterTest() { Stream S = new Stream("S", 100, 1, 1); S.SetState("Initial", DateTime.Now, new WaterPacket(100)); TimeSpan ts = new TimeSpan(0, 1, 0); int Id = 2; IWaterPacket expected = new WaterPacket(Id, 200); IWaterPacket actual; S.WaterLevel = 8; GroundWaterBoundary b = new GroundWaterBoundary(S, 0.001, 10, 100, XYPolygon.GetSquare(250)); b.WaterSample = expected; S.GroundwaterBoundaries.Add(b); S.Update(S.CurrentTime.Add(ts)); actual = S.CurrentStoredWater; double ExpectedVolume = b.GetSourceWater(DateTime.Now, ts).Volume; Assert.AreEqual(expected.Composition.Keys.First(), actual.Composition.Keys.First()); Assert.AreEqual(100, actual.Volume, 0.000001); S.Update(S.CurrentTime.Add(ts)); actual = S.CurrentStoredWater; Assert.AreEqual(expected.Composition.Keys.First(), actual.Composition.Keys.First()); Assert.AreEqual(100, actual.Volume, 0.000001); S.AddWaterPacket(DateTime.Now, DateTime.Now, expected); S.Update(S.CurrentTime.Add(ts)); actual = S.CurrentStoredWater; Assert.AreEqual(100, actual.Volume, 0.000001); }
public void TracerTest() { int count = 3; double length = 10870; DateTime Start = new DateTime(2000, 1, 1); List <Lake> lakes = NetworkBuilder.CreateConnectedLakes(count); foreach (Lake L in lakes) { L.SurfaceArea = XYPolygon.GetSquare(length / count); L.Depth = 1; L.SetState("Initial", Start, new WaterPacket(L.Volume)); } Chemical c = ChemicalFactory.Instance.GetChemical(ChemicalNames.Cl); SinkSourceBoundary fb = new SinkSourceBoundary(10870.0 / (8.49 * 3600)); fb.WaterSample = new WaterPacket(1); lakes.First().Sources.Add(fb); WaterPacket plug = new WaterPacket(1); plug.AddChemical(c, 10000); lakes.First().AddWaterPacket(Start, Start.AddHours(1), plug.DeepClone()); lakes.First().Output.LogChemicalConcentration(c); lakes.Last().Output.LogChemicalConcentration(c); Stream us = new Stream("us", 1, 1, 1); us.Sources.Add(fb); Stream s = new Stream("s", 1000, 1, 1); Lake L2 = new Lake("L2", 870); Stream s1 = new Stream("s1", 9000, 1, 1); s.AddWaterPacket(Start, Start.AddSeconds(1), plug.DeepClone()); s1.Output.LogChemicalConcentration(c); us.AddDownStreamWaterBody(s); s.AddDownStreamWaterBody(L2); L2.AddDownStreamWaterBody(s1); Model m = new Model(); m._waterBodies.AddRange(lakes.Cast <IWaterBody>()); m._waterBodies.Add((IWaterBody)us); m._waterBodies.Add((IWaterBody)s); m._waterBodies.Add((IWaterBody)L2); m._waterBodies.Add((IWaterBody)s1); m.SetState("Initial", Start, new WaterPacket(1)); m.MoveInTime(Start.AddHours(15), TimeSpan.FromMinutes(1)); lakes.Last().Output.Save(@"C:\temp\LastLake.xts"); s1.Output.Save(@"C:\temp\Stream.xts"); int n = 15; List <IWaterBody> wbs = NetworkBuilder.CreateCombo(n, 10870 / n / 2.0); foreach (IWaterBody wb in wbs) { wb.SetState("Initial", Start, new WaterPacket(wb.Volume)); } wbs.First().AddWaterPacket(Start, Start.AddHours(1), plug.DeepClone()); us.AddDownStreamWaterBody(wbs.First()); us.RestoreState("Initial"); m._waterBodies.Clear(); m._waterBodies.Add(us); m._waterBodies.AddRange(wbs); m.SetState("Initial", Start, new WaterPacket(1)); ((Stream)wbs.Last()).Output.LogChemicalConcentration(c); m.MoveInTime(Start.AddHours(15), TimeSpan.FromMinutes(1)); ((Stream)wbs.Last()).Output.Save(@"C:\temp\Stream.xts"); }