def UrbanQTotal(NYrs, DaysMonth, NRur, NUrb, Temp, InitSnow_0, Prec, Area,
CNI_0, AntMoist_0, Grow_0, CNP_0, Imper, ISRR, ISRA):
nlu = NLU(NRur, NUrb)
result = zeros((NYrs, 12, 31))
water = Water(NYrs, DaysMonth, InitSnow_0, Temp, Prec)
urb_area_total = UrbAreaTotal(NRur, NUrb, Area)
qrun_i = QrunI(NYrs, DaysMonth, NRur, NUrb, Temp, InitSnow_0, Prec, CNI_0,
AntMoist_0, Grow_0)
qrun_p = QrunP(NYrs, DaysMonth, NRur, NUrb, Temp, InitSnow_0, Prec, CNP_0,
AntMoist_0, Grow_0)
lu = LU(NRur, NUrb)
for Y in range(NYrs):
for i in range(12):
for j in range(DaysMonth[Y][i]):
if Temp[Y][i][j] > 0 and water[Y][i][j] > 0.01:
if water[Y][i][j] < 0.05:
pass
else:
for l in range(NRur, nlu):
if urb_area_total > 0:
result[Y][i][j] += (
(qrun_i[Y][i][j][l] *
(Imper[l] * (1 - ISRR[lu[l]]) *
(1 - ISRA[lu[l]])) + qrun_p[Y][i][j][l] *
(1 - (Imper[l] * (1 - ISRR[lu[l]]) *
(1 - ISRA[lu[l]])))) * Area[l] /
urb_area_total)
return result
def WashImperv_f(NYrs, DaysMonth, InitSnow_0, Temp, Prec, CNI_0, AntMoist_0,
Grow_0, NRur, NUrb):
nlu = NLU(NRur, NUrb)
water = Water_f(NYrs, DaysMonth, InitSnow_0, Temp, Prec)
qruni = QrunI_f(NYrs, DaysMonth, NRur, NUrb, Temp, InitSnow_0, Prec, CNI_0,
AntMoist_0, Grow_0)
return WashImperv_inner(NYrs, DaysMonth, Temp, NRur, nlu, water, qruni)
def CNI_f(NRur, NUrb, CNI_0):
nlu = NLU(NRur, NUrb)
result = zeros((3, nlu))
result[0] = CNI_0[1] / (2.334 - 0.01334 * CNI_0[1][1])
result[1] = CNI_0[1]
result[2] = CNI_0[1] / (0.4036 + 0.0059 * CNI_0[1])
return result
def QrunI(NYrs, DaysMonth, NRur, NUrb, Temp, InitSnow_0, Prec, CNI_0,
AntMoist_0, Grow_0):
result = zeros((NYrs, 12, 31, 16)) # TODO: should this be nlu?
nlu = NLU(NRur, NUrb)
water = Water(NYrs, DaysMonth, InitSnow_0, Temp, Prec)
cni = CNI(NRur, NUrb, CNI_0)
c_num_imperv_reten = CNumImpervReten(NYrs, DaysMonth, Temp, Prec,
InitSnow_0, AntMoist_0, NRur, NUrb,
CNI_0, Grow_0)
for Y in range(NYrs):
for i in range(12):
for j in range(DaysMonth[Y][i]):
if Temp[Y][i][j] > 0 and water[Y][i][j] > 0.01:
for l in range(NRur, nlu): # TODO: what is this for?
result[Y][i][j][l] = 0
if water[Y][i][j] < 0.05:
pass
else:
for l in range(NRur, nlu):
if cni[1][l] > 0:
if water[Y][i][j] >= 0.2 * c_num_imperv_reten[
Y][i][j][l]:
result[Y][i][j][l] = (
water[Y][i][j] -
0.2 * c_num_imperv_reten[Y][i][j][l]
)**2 / (water[Y][i][j] + 0.8 *
c_num_imperv_reten[Y][i][j][l])
return result
def NetSolidLoad_f(NYrs, DaysMonth, Temp, InitSnow_0, Prec, NRur, NUrb, Area,
CNI_0, AntMoist_0, Grow_0, CNP_0, Imper, ISRR, ISRA,
Qretention, PctAreaInfil, Nqual, LoadRateImp, LoadRatePerv,
Storm, UrbBMPRed, DisFract, FilterWidth, PctStrmBuf):
nlu = NLU(NRur, NUrb)
result = zeros((NYrs, 12, 31, nlu - NRur, Nqual))
water = Water_f(NYrs, DaysMonth, InitSnow_0, Temp, Prec)
adjurbanqtotal = AdjUrbanQTotal_f(NYrs, DaysMonth, Temp, InitSnow_0, Prec,
NRur, NUrb, Area, CNI_0, AntMoist_0,
Grow_0, CNP_0, Imper, ISRR, ISRA,
Qretention, PctAreaInfil)
dissurfaceload = DisSurfLoad_f(NYrs, DaysMonth, InitSnow_0, Temp, Prec,
Nqual, NRur, NUrb, Area, CNI_0, AntMoist_0,
Grow_0, CNP_0, Imper, ISRR, ISRA,
Qretention, PctAreaInfil, LoadRateImp,
LoadRatePerv, Storm, UrbBMPRed, DisFract,
FilterWidth, PctStrmBuf)
surfaceload_1 = SurfaceLoad_1_f(NYrs, DaysMonth, InitSnow_0, Temp, Prec,
NRur, NUrb, Area, CNI_0, AntMoist_0,
Grow_0, CNP_0, Imper, ISRR, ISRA,
Qretention, PctAreaInfil, Nqual,
LoadRateImp, LoadRatePerv, Storm,
UrbBMPRed, FilterWidth, PctStrmBuf)
nonzero = where((Temp > 0) & (water > 0.01) & (adjurbanqtotal > 0.001))
result[nonzero] = surfaceload_1[nonzero] - dissurfaceload[nonzero]
return sum(result, axis=3)
def WashPerv(NYrs, DaysMonth, InitSnow_0, Temp, Prec, CNP_0, AntMoist_0,
Grow_0, NRur, NUrb):
pervaccum = zeros(16)
nlu = NLU(NRur, NUrb)
water = Water(NYrs, DaysMonth, InitSnow_0, Temp, Prec)
qrunp = QrunP(NYrs, DaysMonth, NRur, NUrb, Temp, InitSnow_0, Prec, CNP_0,
AntMoist_0, Grow_0)
washperv = zeros((NYrs, 12, 31, 16))
carryover = zeros(16)
for Y in range(NYrs):
for i in range(12):
for j in range(DaysMonth[Y][i]):
for l in range(nlu):
pervaccum[l] = carryover[l]
pervaccum[l] = (pervaccum[l] * exp(-0.12) + (1 / 0.12) *
(1 - exp(-0.12)))
if Temp[Y][i][j] > 0 and water[Y][i][j] > 0.01:
if water[Y][i][j] < 0.05:
pass
else:
for l in range(NRur, nlu):
washperv[Y][i][j][l] = (1 - math.exp(
-1.81 * qrunp[Y][i][j][l])) * pervaccum[l]
pervaccum[l] -= washperv[Y][i][j][l]
else:
pass
for l in range(nlu):
carryover[l] = pervaccum[l]
return washperv
def UrbQRunoff(NYrs, DaysMonth, InitSnow_0, Temp, Prec, NRur, NUrb, CNI_0,
CNP_0, AntMoist_0, Grow_0, Imper, ISRR, ISRA):
result = zeros((NYrs, 16, 12))
nlu = NLU(NRur, NUrb)
water = Water(NYrs, DaysMonth, InitSnow_0, Temp, Prec)
qruni = QrunI(NYrs, DaysMonth, NRur, NUrb, Temp, InitSnow_0, Prec, CNI_0,
AntMoist_0, Grow_0)
qrunp = QrunP(NYrs, DaysMonth, NRur, NUrb, Temp, InitSnow_0, Prec, CNP_0,
AntMoist_0, Grow_0)
lu = LU(NRur, NUrb)
for Y in range(NYrs):
for i in range(12):
for l in range(nlu):
result[Y, l, i] = 0
for Y in range(NYrs):
for i in range(12):
for j in range(DaysMonth[Y][i]):
if Temp[Y][i][j] > 0 and water[Y][i][j] > 0.01:
if water[Y][i][j] < 0.05:
pass
else:
for l in range(NRur, nlu):
result[Y][l][i] += (qruni[Y][i][j][l] *
(Imper[l] * (1 - ISRR[lu[l]]) *
(1 - ISRA[lu[l]])) +
qrunp[Y][i][j][l] *
(1 - (Imper[l] *
(1 - ISRR[lu[l]]) *
(1 - ISRA[lu[l]]))))
else:
pass
return result
def LuTotPhos(NYrs, DaysMonth, InitSnow_0, Temp, Prec, AntMoist_0, NRur, NUrb,
CN, Grow_0, Area, PhosConc, ManPhos, ManuredAreas,
FirstManureMonth, LastManureMonth, FirstManureMonth2,
LastManureMonth2, SedDelivRatio_0, KF, LS, C, P, CNP_0, Imper,
ISRR, ISRA, Qretention, PctAreaInfil, Nqual, LoadRateImp,
LoadRatePerv, Storm, UrbBMPRed, FilterWidth, PctStrmBuf, Acoef,
SedPhos, CNI_0):
result = zeros((NYrs, 16))
p_runoff = pRunoff(NYrs, DaysMonth, InitSnow_0, Temp, Prec, AntMoist_0,
NRur, NUrb, CN, Grow_0, Area, PhosConc, ManuredAreas,
FirstManureMonth, LastManureMonth, ManPhos,
FirstManureMonth2, LastManureMonth2)
sed_deliv_ratio = SedDelivRatio(SedDelivRatio_0)
eros_washoff = ErosWashoff(NYrs, DaysMonth, InitSnow_0, Temp, Prec, NRur,
NUrb, Acoef, KF, LS, C, P, Area)
lu_load = LuLoad(NYrs, DaysMonth, Temp, InitSnow_0, Prec, NRur, NUrb, Area,
CNI_0, AntMoist_0, Grow_0, CNP_0, Imper, ISRR, ISRA,
Qretention, PctAreaInfil, Nqual, LoadRateImp,
LoadRatePerv, Storm, UrbBMPRed, FilterWidth, PctStrmBuf)
nlu = NLU(NRur, NUrb)
for Y in range(NYrs):
for i in range(12):
# Add in the urban calucation for sediment
for l in range(NRur):
result[Y][l] += p_runoff[Y][i][l]
result[Y][l] += 0.001 * sed_deliv_ratio * eros_washoff[Y][l][
i] * SedPhos
for l in range(NRur, nlu):
result[Y][l] += lu_load[Y][l][1] / NYrs / 2
return result
def SurfaceLoad_1_f(NYrs, DaysMonth, InitSnow_0, Temp, Prec, NRur, NUrb, Area,
CNI_0, AntMoist_0, Grow_0, CNP_0, Imper, ISRR, ISRA,
Qretention, PctAreaInfil, Nqual, LoadRateImp, LoadRatePerv,
Storm, UrbBMPRed, FilterWidth, PctStrmBuf):
nlu = NLU(NRur, NUrb)
result = zeros((NYrs, 12, 31, nlu - NRur, Nqual))
water = Water_f(NYrs, DaysMonth, InitSnow_0, Temp, Prec)
adjurbanqtotal = AdjUrbanQTotal_f(NYrs, DaysMonth, Temp, InitSnow_0, Prec,
NRur, NUrb, Area, CNI_0, AntMoist_0,
Grow_0, CNP_0, Imper, ISRR, ISRA,
Qretention, PctAreaInfil)
surfaceload = SurfaceLoad_f(NYrs, DaysMonth, InitSnow_0, Temp, Prec, NRur,
NUrb, Area, CNI_0, AntMoist_0, Grow_0, CNP_0,
Imper, ISRR, ISRA, Qretention, PctAreaInfil,
Nqual, LoadRateImp, LoadRatePerv, Storm,
UrbBMPRed)
retentioneff = RetentionEff_f(NYrs, DaysMonth, InitSnow_0, Temp, Prec,
Qretention, NRur, NUrb, Area, CNI_0,
AntMoist_0, Grow_0, CNP_0, Imper, ISRR, ISRA,
PctAreaInfil)[:, :, :, None, None]
retentioneff = repeat(repeat(retentioneff, nlu - NRur, axis=3),
Nqual,
axis=4)
filtereff = FilterEff_f(FilterWidth)
nonzero = where((Temp > 0) & (water > 0.01) & (adjurbanqtotal > 0.001))
result[nonzero] = surfaceload[nonzero] * (1 - retentioneff[nonzero]) * (
1 - (filtereff * PctStrmBuf))
return result
def RurQRunoff(NYrs, DaysMonth, InitSnow_0, Temp, Prec, AntMoist_0, NRur, NUrb,
CN, Grow_0):
result = zeros((NYrs, 16, 12))
nlu = NLU(NRur, NUrb)
water = Water(NYrs, DaysMonth, InitSnow_0, Temp, Prec)
retention = Retention(NYrs, DaysMonth, Temp, Prec, InitSnow_0, AntMoist_0,
NRur, NUrb, CN, Grow_0)
qrun = Qrun(NYrs, DaysMonth, Temp, InitSnow_0, Prec, NRur, NUrb, CN,
AntMoist_0, Grow_0)
for Y in range(NYrs):
for i in range(12):
for l in range(nlu):
result[Y, l, i] = 0.0
for Y in range(NYrs):
for i in range(12):
for j in range(DaysMonth[Y][i]):
if Temp[Y][i][j] > 0 and water[Y][i][j] > 0.01:
for l in range(NRur):
if CN[l] > 0:
if water[Y][i][j] >= 0.2 * retention[Y][i][j][l]:
result[Y][l][i] += qrun[Y][i][j][l]
else:
pass
else:
pass
else:
pass
return result
def NewCN_f(NRur, NUrb, CN):
nlu = NLU(NRur, NUrb)
result = zeros((3, nlu))
result[0, :] = CN / (2.334 - 0.01334 * CN)
result[2, :] = CN / (0.4036 + 0.0059 * CN)
result[2, :][where(result[2, :] > 100)] = 100
return result
def WashImperv(NYrs, DaysMonth, InitSnow_0, Temp, Prec, CNI_0, AntMoist_0,
Grow_0, NRur, NUrb):
result = zeros((NYrs, 12, 31, 16))
impervaccum = zeros(16)
carryover = zeros(16)
nlu = NLU(NRur, NUrb)
water = Water(NYrs, DaysMonth, InitSnow_0, Temp, Prec)
qruni = QrunI(NYrs, DaysMonth, NRur, NUrb, Temp, InitSnow_0, Prec, CNI_0,
AntMoist_0, Grow_0)
for Y in range(NYrs):
for i in range(12):
for j in range(DaysMonth[Y][i]):
for l in range(nlu):
impervaccum[l] = carryover[l]
impervaccum[l] = (impervaccum[l] * exp(-0.12) +
(1 / 0.12) * (1 - exp(-0.12)))
if Temp[Y][i][j] > 0 and water[Y][i][j] > 0.01:
if water[Y][i][j] < 0.05:
pass
else:
for l in range(NRur, nlu):
result[Y][i][j][l] = (1 - math.exp(
-1.81 * qruni[Y][i][j][l])) * impervaccum[l]
impervaccum[l] -= result[Y][i][j][l]
else:
pass
for l in range(nlu):
carryover[l] = impervaccum[l]
return result
def LuLoad(NYrs, DaysMonth, Temp, InitSnow_0, Prec, NRur, NUrb, Area, CNI_0,
AntMoist_0, Grow_0, CNP_0, Imper, ISRR, ISRA, Qretention,
PctAreaInfil, Nqual, LoadRateImp, LoadRatePerv, Storm, UrbBMPRed,
FilterWidth, PctStrmBuf):
result = zeros((NYrs, 16, 3))
water = Water(NYrs, DaysMonth, InitSnow_0, Temp, Prec)
nlu = NLU(NRur, NUrb)
adjurbanqtotal = AdjUrbanQTotal(NYrs, DaysMonth, Temp, InitSnow_0, Prec,
NRur, NUrb, Area, CNI_0, AntMoist_0,
Grow_0, CNP_0, Imper, ISRR, ISRA,
Qretention, PctAreaInfil)
surfaceload_1 = SurfaceLoad_1(NYrs, DaysMonth, InitSnow_0, Temp, Prec,
NRur, NUrb, Area, CNI_0, AntMoist_0, Grow_0,
CNP_0, Imper, ISRR, ISRA, Qretention,
PctAreaInfil, Nqual, LoadRateImp,
LoadRatePerv, Storm, UrbBMPRed, FilterWidth,
PctStrmBuf)
for Y in range(NYrs):
for i in range(12):
for j in range(DaysMonth[Y][i]):
if Temp[Y][i][j] > 0 and water[Y][i][j] > 0.01:
if adjurbanqtotal[Y][i][j] > 0.001:
for l in range(NRur, nlu):
for q in range(Nqual):
result[Y][l][q] += surfaceload_1[Y][i][j][l][q]
else:
pass
else:
pass
return result
def CNI(NRur, NUrb, CNI_0):
nlu = NLU(NRur, NUrb)
result = zeros((3, nlu))
for l in range(NRur, nlu):
result[0][l] = CNI_0[1][l] / (2.334 - 0.01334 * CNI_0[1][1])
result[1][l] = CNI_0[1][l]
result[2][l] = CNI_0[1][l] / (0.4036 + 0.0059 * CNI_0[1][l])
return result
def CNumPerv_f(NYrs, DaysMonth, Temp, NRur, NUrb, CNP_0, InitSnow_0, Prec, Grow_0, AntMoist_0):
nlu = NLU(NRur, NUrb)
cnp = CNP_f(NRur, NUrb, CNP_0)
water = Water_f(NYrs, DaysMonth, InitSnow_0, Temp, Prec)
melt = Melt_1_f(NYrs, DaysMonth, InitSnow_0, Temp, Prec)
grow_factor = GrowFactor(Grow_0) # TODO: some bug in cnumperv_inner causes an error if this is switched to _f
amc5 = AMC5_yesterday(NYrs, DaysMonth, Temp, Prec, InitSnow_0, AntMoist_0)
return CNumPerv_inner(NYrs, DaysMonth, Temp, NRur, nlu, cnp, water, melt, grow_factor, amc5)
def AreaTotal(NRur, NUrb, Area):
result = 0
nlu = NLU(NRur, NUrb)
for l in range(NRur):
result += Area[l]
for l in range(NRur, nlu):
result += Area[l]
return result
def NewCN(NRur, NUrb, CN):
nlu = NLU(NRur, NUrb)
result = zeros((3, nlu))
for l in range(NRur):
result[0][l] = CN[l] / (2.334 - 0.01334 * CN[l])
result[2][l] = CN[l] / (0.4036 + 0.0059 * CN[l])
if result[2][l] > 100:
result[2][l] = 100
return result
def SurfaceLoad(NYrs, DaysMonth, InitSnow_0, Temp, Prec, NRur, NUrb, Area,
CNI_0, AntMoist_0, Grow_0, CNP_0, Imper, ISRR, ISRA,
Qretention, PctAreaInfil, Nqual, LoadRateImp, LoadRatePerv,
Storm, UrbBMPRed):
result = zeros((NYrs, 12, 31, 16, Nqual))
water = Water(NYrs, DaysMonth, InitSnow_0, Temp, Prec)
adjurbanqtotal = AdjUrbanQTotal(NYrs, DaysMonth, Temp, InitSnow_0, Prec,
NRur, NUrb, Area, CNI_0, AntMoist_0,
Grow_0, CNP_0, Imper, ISRR, ISRA,
Qretention, PctAreaInfil)
nlu = NLU(NRur, NUrb)
washimperv = WashImperv(NYrs, DaysMonth, InitSnow_0, Temp, Prec, CNI_0,
AntMoist_0, Grow_0, NRur, NUrb)
washperv = WashPerv(NYrs, DaysMonth, InitSnow_0, Temp, Prec, CNP_0,
AntMoist_0, Grow_0, NRur, NUrb)
lu_1 = LU_1(NRur, NUrb)
urbloadred = UrbLoadRed(NYrs, DaysMonth, InitSnow_0, Temp, Prec, NRur,
NUrb, Area, CNI_0, AntMoist_0, Grow_0, CNP_0,
Imper, ISRR, ISRA, Qretention, PctAreaInfil, Nqual,
Storm, UrbBMPRed)
for Y in range(NYrs):
for i in range(12):
for j in range(DaysMonth[Y][i]):
if Temp[Y][i][j] > 0 and water[Y][i][j] > 0.01:
if adjurbanqtotal[Y][i][j] > 0.001:
for l in range(NRur, nlu):
for q in range(Nqual):
if Area[l] > 0:
result[Y][i][j][l][q] = (((
LoadRateImp[l][q] *
washimperv[Y][i][j][l] *
((Imper[l] * (1 - ISRR[lu_1[l]]) *
(1 - ISRA[lu_1[l]]))
# * (SweepFrac[i] + (
# (1 - SweepFrac[i]) * ((1 - UrbSweepFrac) * Area[l]) / Area[l]))
* 1
) # TODO For some reason, this commented out code always needs to evaluate to 1 in order for the separation to occur
+ LoadRatePerv[l][q] *
washperv[Y][i][j][l] *
(1 -
(Imper[l] * (1 - ISRR[lu_1[l]]) *
(1 - ISRA[lu_1[l]])))) * Area[l]) -
urbloadred[Y][i]
[j][l][q])
else:
result[Y][i][j][l][q] = 0
if result[Y][i][j][l][q] < 0:
result[Y][i][j][l][q] = 0
else:
pass
else:
pass
else:
pass
return result
def CNumImperv_f(NYrs, NRur, NUrb, DaysMonth, InitSnow_0, Temp, Prec, CNI_0,
Grow_0, AntMoist_0):
nlu = NLU(NRur, NUrb)
cni = CNI_f(NRur, NUrb, CNI_0)
water = Water_f(NYrs, DaysMonth, InitSnow_0, Temp, Prec)
melt = Melt_1_f(NYrs, DaysMonth, InitSnow_0, Temp, Prec)
grow_factor = GrowFactor_f(Grow_0)
amc5 = AMC5_yesterday(NYrs, DaysMonth, Temp, Prec, InitSnow_0, AntMoist_0)
return CNumImperv_inner(NYrs, NRur, DaysMonth, Temp, nlu, cni, water, melt,
grow_factor, amc5)
def NConc(NRur, NUrb, NitrConc, ManNitr, ManuredAreas, FirstManureMonth,
LastManureMonth, FirstManureMonth2, LastManureMonth2):
nlu = NLU(NRur, NUrb)
result = zeros((12, nlu))
for i in range(12):
for l in range(NRur):
result[i][l] = NitrConc[l]
if l < ManuredAreas and i >= FirstManureMonth and i <= LastManureMonth:
result[i][l] = ManNitr[l]
if l < ManuredAreas and i >= FirstManureMonth2 and i <= LastManureMonth2:
result[i][l] = ManNitr[l]
return result
def AvCNUrb(NRur, NUrb, CNI_0, CNP_0, Imper, Area):
result = 0
nlu = NLU(NRur, NUrb)
cni = CNI(NRur, NUrb, CNI_0)
cnp = CNP(NRur, NUrb, CNP_0)
urbareatotal = UrbAreaTotal(NRur, NUrb, Area)
for l in range(NRur, nlu):
# Calculate average area-weighted CN for urban areas
if urbareatotal > 0:
result += ((Imper[l] * cni[1][l] + (1 - Imper[l]) * cnp[1][l]) *
Area[l] / urbareatotal)
return result
def PConc(NRur, NUrb, PhosConc, ManPhos, ManuredAreas, FirstManureMonth,
LastManureMonth, FirstManureMonth2, LastManureMonth2):
nlu = NLU(NRur, NUrb)
result = zeros((12, nlu))
for i in range(12):
for l in range(NRur):
result[i][l] = PhosConc[l]
# MANURE SPREADING DAYS FOR FIRST SPREADING PERIOD
if l < ManuredAreas and i >= FirstManureMonth and i <= LastManureMonth:
result[i][l] = ManPhos[l]
# MANURE SPREADING DAYS FOR SECOND SPREADING PERIOD
if l < ManuredAreas and i >= FirstManureMonth2 and i <= LastManureMonth2:
result[i][l] = ManPhos[l]
return result
def Retention_f(NYrs, DaysMonth, Temp, Prec, InitSnow_0, AntMoist_0, NRur,
NUrb, CN, Grow_0):
nlu = NLU(NRur, NUrb)
result = zeros((NYrs, 12, 31, nlu))
c_num = CNum_f(NYrs, DaysMonth, Temp, Prec, InitSnow_0, AntMoist_0, CN,
NRur, NUrb, Grow_0)
cnrur = tile(CN[:NRur][None, None, None, :], (NYrs, 12, 31, 1))
water = repeat(Water_f(NYrs, DaysMonth, InitSnow_0, Temp, Prec)[:, :, :,
None],
NRur,
axis=3)
TempE = repeat(Temp[:, :, :, None], NRur, axis=3)
result[where((TempE > 0) & (water > 0.01)
& (cnrur > 0))] = 2540 / c_num[where(
(TempE > 0) & (water > 0.01) & (cnrur > 0))] - 25.4
result[where(result < 0)] = 0
return result
def CNumPerv(NYrs, DaysMonth, Temp, NRur, NUrb, CNP_0, InitSnow_0, Prec, Grow_0, AntMoist_0):
nlu = NLU(NRur, NUrb)
result = zeros((NYrs, 12, 31, nlu))
cnp = CNP(NRur, NUrb, CNP_0)
water = Water(NYrs, DaysMonth, InitSnow_0, Temp, Prec)
melt = Melt(NYrs, DaysMonth, Temp, InitSnow_0, Prec)
grow_factor = GrowFactor(Grow_0)
amc5 = AMC5(NYrs, DaysMonth, Temp, Prec, InitSnow_0, AntMoist_0)
for Y in range(NYrs):
for i in range(12):
for j in range(DaysMonth[Y][i]):
if Temp[Y][i][j] > 0 and water[Y][i][j] > 0.01:
if water[Y][i][j] < 0.05:
pass
else:
for l in range(NRur, nlu):
if cnp[1][l] > 0:
if melt[Y][i][j] <= 0:
if grow_factor[i] > 0:
# Growing season
if get_value_for_yesterday(amc5, 0, Y, i, j, DaysMonth) >= 5.33:
result[Y][i][j][l] = cnp[2][l]
elif get_value_for_yesterday(amc5, 0, Y, i, j, DaysMonth) < 3.56:
result[Y][i][j][l] = cnp[0][l] + (
cnp[1][l] - cnp[0][l]) * \
get_value_for_yesterday(amc5, 0, Y, i, j,
DaysMonth) / 3.56
else:
result[Y][i][j][l] = cnp[1][l] + (cnp[2][l] - cnp[1][l]) * (
get_value_for_yesterday(amc5, 0, Y, i, j, DaysMonth) - 3.56) / 1.77
else:
# Dormant season
if get_value_for_yesterday(amc5, 0, Y, i, j, DaysMonth) >= 2.79:
result[Y][i][j][l] = cnp[2][l]
elif get_value_for_yesterday(amc5, 0, Y, i, j, DaysMonth) < 1.27:
result[Y][i][j][l] = cnp[0][l] + (
cnp[1][l] - cnp[0][l]) * \
get_value_for_yesterday(amc5, 0, Y, i, j,
DaysMonth) / 1.27
else:
result[Y][i][j][l] = cnp[1][l] + (cnp[2][l] - cnp[1][l]) * (
get_value_for_yesterday(amc5, 0, Y, i, j, DaysMonth) - 1.27) / 1.52
else:
result[Y][i][j][l] = cnp[2][l]
return result
def LuRunoff(NYrs, DaysMonth, InitSnow_0, Temp, Prec, NRur, NUrb, CNI_0, CNP_0,
AntMoist_0, Grow_0, Imper, ISRR, ISRA, CN):
result = zeros((NYrs, 16))
nlu = NLU(NRur, NUrb)
urb_q_runoff = UrbQRunoff(NYrs, DaysMonth, InitSnow_0, Temp, Prec, NRur, NUrb, CNI_0, CNP_0,
AntMoist_0, Grow_0, Imper, ISRR, ISRA)
rur_q_runoff = RurQRunoff(NYrs, DaysMonth, InitSnow_0, Temp, Prec, AntMoist_0, NRur, NUrb, CN, Grow_0)
for Y in range(NYrs):
for i in range(12):
# Calculate landuse runoff for rural areas
for l in range(NRur):
result[Y][l] += rur_q_runoff[Y][l][i]
for i in range(12):
# Calculate landuse runoff for urban areas
for l in range(NRur, nlu):
result[Y][l] += urb_q_runoff[Y][l][i]
return result
def Qrun_f(NYrs, DaysMonth, Temp, InitSnow_0, Prec, NRur, NUrb, CN, AntMoist_0,
Grow_0):
nlu = NLU(NRur, NUrb)
result = zeros((NYrs, 12, 31, nlu))
water = repeat(Water_f(NYrs, DaysMonth, InitSnow_0, Temp, Prec)[:, :, :,
None],
nlu,
axis=3)
TempE = repeat(Temp[:, :, :, None], nlu, axis=3)
cnrur = tile(CN[None, None, None, :], (NYrs, 12, 31, 1))
retention = Retention_f(NYrs, DaysMonth, Temp, Prec, InitSnow_0,
AntMoist_0, NRur, NUrb, CN, Grow_0)
retention02 = 0.2 * retention
nonzero = where((TempE > 0) & (water > 0.01) & (water >= retention02)
& (cnrur > 0))
result[nonzero] = (water[nonzero] - retention02[nonzero])**2 / (
water[nonzero] + 0.8 * retention[nonzero])
return result
def Retention(NYrs, DaysMonth, Temp, Prec, InitSnow_0, AntMoist_0, NRur, NUrb,
CN, Grow_0):
nlu = NLU(NRur, NUrb)
result = zeros((NYrs, 12, 31, nlu)) # Why nlu ?
c_num = CNum(NYrs, DaysMonth, Temp, Prec, InitSnow_0, AntMoist_0, CN, NRur,
NUrb, Grow_0)
water = Water(NYrs, DaysMonth, InitSnow_0, Temp, Prec)
for Y in range(NYrs):
for i in range(12):
for j in range(DaysMonth[Y][i]):
if Temp[Y][i][j] > 0 and water[Y][i][j] > 0.01:
for l in range(NRur):
if CN[l] > 0: # TODO:CN is set to zero in datamodel
result[Y][i][j][
l] = 2540 / c_num[Y][i][j][l] - 25.4
if result[Y][i][j][l] < 0:
result[Y][i][j][l] = 0
return result
def CNumImpervReten_f(NYrs, DaysMonth, Temp, Prec, InitSnow_0, AntMoist_0,
NRur, NUrb, CNI_0, Grow_0):
cni = CNI_f(NRur, NUrb, CNI_0)
cni_1 = tile(cni[1][None, None, None, :], (NYrs, 12, 31, 1))
c_num_imperv = CNumImperv_f(NYrs, NRur, NUrb, DaysMonth, InitSnow_0, Temp,
Prec, CNI_0, Grow_0, AntMoist_0)
nlu = NLU(NRur, NUrb)
water = repeat(Water_f(NYrs, DaysMonth, InitSnow_0, Temp, Prec)[:, :, :,
None],
nlu,
axis=3)
result = zeros((NYrs, 12, 31, nlu))
TempE = repeat(Temp[:, :, :, None], nlu, axis=3)
result[where((TempE > 0) & (water >= 0.05)
& (cni_1 > 0))] = 2540 / c_num_imperv[where(
(TempE > 0) & (water >= 0.05) & (cni_1 > 0))] - 25.4
result[where(result < 0)] = 0
return result
def QrunP_f(NYrs, DaysMonth, NRur, NUrb, Temp, InitSnow_0, Prec, CNP_0,
AntMoist_0, Grow_0):
nlu = NLU(NRur, NUrb)
result = zeros((NYrs, 12, 31, nlu))
water = repeat(Water_f(NYrs, DaysMonth, InitSnow_0, Temp, Prec)[:, :, :,
None],
nlu,
axis=3)
TempE = repeat(Temp[:, :, :, None], nlu, axis=3)
c_num_perv_reten = CNumPervReten_f(NYrs, DaysMonth, Temp, Prec, InitSnow_0,
AntMoist_0, NRur, NUrb, CNP_0, Grow_0)
c_num_perv_reten02 = 0.2 * c_num_perv_reten
cnp = CNP_f(NRur, NUrb, CNP_0)
cnp_1 = tile(cnp[1][None, None, None, :], (NYrs, 12, 31, 1))
nonzero = where((TempE > 0) & (water >= 0.05) & (cnp_1 > 0)
& (water >= c_num_perv_reten02))
result[nonzero] = (water[nonzero] - c_num_perv_reten02[nonzero])**2 / (
water[nonzero] + 0.8 * c_num_perv_reten[nonzero])
return result
def ErosWashoff(NYrs, DaysMonth, InitSnow_0, Temp, Prec, NRur, NUrb, Acoef, KF,
LS, C, P, Area):
result = zeros((NYrs, 16, 12))
nlu = NLU(NRur, NUrb)
water = Water(NYrs, DaysMonth, InitSnow_0, Temp, Prec)
rureros = RurEros(NYrs, DaysMonth, Temp, InitSnow_0, Prec, Acoef, NRur, KF,
LS, C, P, Area)
for Y in range(NYrs):
for i in range(12):
for l in range(nlu):
result[Y, l, i] = 0
for Y in range(NYrs):
for i in range(12):
for j in range(DaysMonth[Y][i]):
if Temp[Y][i][j] > 0 and water[Y][i][j] > 0.01:
for l in range(NRur):
result[Y][l][i] = result[Y][l][i] + rureros[Y][i][j][l]
else:
pass
return result
