-
Notifications
You must be signed in to change notification settings - Fork 0
/
Copy pathcalib.jl
207 lines (174 loc) · 9.48 KB
/
calib.jl
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
println("Start calibration:\n")
# parameters
delta = 0.05 # depreciation rate
r0 = 0.04 # real interest rate
sigma = 0.9 # elasticity of inter-temporal substitution
sigL = 0.3 # labor supply elasticity
# note: ages are off-set by 1 year, e.g. age group 1 contains 0-year olds
fag = 14 # first economically active age-group (age 15)
rag0 = 61.3 # retirement age group (retirement age 62.3), non-whole numbers allowed
iag0 = 51 # first age group giving inter-vivo transfers
ivpc = 0.2 # intervivo transfer received per capita
# some normalizations
N0 = 100.0 # population
Y0 = 100.0 # GDP
L0 = 30.0 # total labor supply in efficiency units
w0 = 2.0 # wage rate
Cons0 = 0.55*Y0 # consumption share (calibrated using taul0)
### DEMOGRAPHY ###
for i in 1:nag
gamv0[i] = 1-0.89^(nag-i+1) # some simple profile
end
# survival of last age group is 0
gamv0[nag] = 0
# compute demography
Nv0[1] = 1
for i in 2:nag
Nv0[i] = Nv0[i-1]*gamv0[i-1]
end
# rescale population
NB0 = 1/sum(Nv0)*N0
Nv0 = Nv0/sum(Nv0)*N0
avage0 = sum(Nv0.*collect(0:(nag-1)))/N0
report("REPORT: Average age:",avage0)
lifeexpect0 = lifeexpect(gamv0)
report("REPORT: Life-expectancy at age 0:", lifeexpect0[1])
report("REPORT: Life-expectancy at age 65:", lifeexpect0[66])
### AGE PROFILES ###
# indicator for not-retired
notretv0[1:floor(Int,rag0)] .= 1 # not retired
notretv0[floor(Int,rag0)+1] = rag0-floor(rag0) # partly retired
# intervivo-transfers
ivv0[iag0:nag] = -seq(ivpc,ivpc*2,nag-iag0+1) # some increasing profile (from ivpc to 2*ivpc)
ivv0[fag:(iag0-1)] = -sum(ivv0[iag0:nag].*Nv0[iag0:nag])/sum(Nv0[fag:(iag0-1)])*onescol(iag0-fag)
iv0 = sum(ivv0.*Nv0)
if abs(iv0)>1e-10
error("ERROR: UNBALANCED INTERVIVO TRANSFERS!")
end
thetav0 = zeroscol(nag) # labor productivity parameters
theta_peak = floor(Int,rag0)-10 # assumption: productivity peaks 10 years before retirement
thetav0[fag:theta_peak] = seq(0.7,1.0,theta_peak-fag+1)
thetav0[(theta_peak+1):nag] = seq(1.0,0.1,nag-theta_peak)
ellv0 = L0/sum(Nv0.*thetav0.*notretv0)*onescol(nag) # labor supply
# partition of population
Nc0 = sum(Nv0[1:(fag-1)]) # number of children
Nw0 = sum(notretv0.*Nv0)-Nc0 # number of workers
Nr0 = sum((1.0.-notretv0).*Nv0) # number of retirees
report("REPORT: Old-age dependency ratio:",sum(Nv0[66:nag])/sum(Nv0[16:65]))
report("REPORT: Economic dependency ratio:",(Nc0+Nr0)/Nw0)
report("CHECK: Newborns - deaths:", sum((1.0.-gamv0).*Nv0)-NB0)
report("CHECK: Children + workers + retriees - pop.:", Nc0+Nw0+Nr0-N0)
### POLICY PARAMETERS ###
tauWv0 = 0.15*onescol(nag) # wage tax rate worker & retiree
tauF0 = 0.2 # payroll tax rate
tauC0 = 0.2 # consumption tax rate
tauprof0 = 0.1 # profit tax rate
pv0 = 0.65*sum(w0.*ellv0.*thetav0.*Nv0)/N0*onescol(nag) # old-age pension (65% of average wage earnings)
DG0 = 0.6*Y0 # government debt level (60% of GDP)
# cGv0 is used to balance budget in calibration
cGv0_profile = 0.2*onescol(nag)
cGv0_profile[1:25] = seq(0.4,0.2,25)
cGv0_profile[55:nag] = seq(0.2,1.0,nag-55+1) # some U-shaped profile
# price of consumption and age specific prices and tax rates (but the same for all age groups)
pc0 = 1+tauC0
tauCv0 = tauC0*onescol(nag)
pcv0 = pc0*onescol(nag)
wv0 = w0*onescol(nag)
rv0 = r0*onescol(nag)
LS0 = sum(notretv0.*ellv0.*thetav0.*Nv0) # aggregate labor supply
LD0 = LS0
uck0 = (r0+delta*(1-tauprof0))/(1-tauprof0) # user-cost of capital
K0 = (Y0-(1+tauF0)*w0*LD0)/uck0
Inv0 = delta*K0
alpha = K0*uck0/(K0*uck0+LS0*((1+tauF0)*w0))
qTob0 = (1-tauprof0)*alpha*Y0/K0 + tauprof0*delta + (1-delta) # = 1+r0
TFP0 = Y0/((K0^alpha)*(LS0^(1-alpha)))
#LD0 = ((1-alpha)*TFP0/((1+tauF0)*w0))^(1/alpha)*K0 # also true
TaxF0 = tauprof0*(Y0-(1+tauF0)*w0*LD0-(delta*K0))
Div0 = Y0-(1+tauF0)*w0*LD0-Inv0-TaxF0
V0 = (1+r0)*Div0/r0
# MATCH CALIBRATION TARGETS;
xcalib0 = [0.01, 0.3719, 0.40, 13, 1] # starting guesses for nlsolve()
xout = nlsolve(calibfind,xcalib0,ftol=1e-12)
if maximum(abs.(calibfind(xout.zero))) > 1e-6
error("NEWTON METHOD DID NOT CONVERGE!\n")
end
### CALIBRATION OF LABOR SUPPLY MARGINS ###
# set parl0 in order to reproduce ell0, FOC ell0
parlv0 = (wv0.*(1.0.-tauWv0).*thetav0./pcv0).*(ellv0.^(-1/sigL)).*(Consv0.^(-1/sigma)); parlv0[1:(fag-1)] .= 0
# set parl1 in order to normalize disutility of labor to 0
parlv1 = (sigL/(1+sigL)).*parlv0.*(ellv0.^((1+sigL)/sigL))
dis_totv0= (sigL/(1+sigL)).*parlv0.*(ellv0.^((1+sigL)/sigL)).-parlv1
report("REPORT: Asset-to-output ratio:", A0/Y0)
checkA0 = sum(Av0.*Nv0)-A0
checkAv0 = Av0[nag]+yv0[nag]+ivv0[nag]+abv0[nag]-pc0*Consv0[nag] # end of period assets of last age group are zero
checkN0 = sum(Nv0)-N0
chkcalib = [edy0,edl0,edg0,ediv0,eda0,edab0,checkA0,checkAv0,checkN0]
report("CHECK: Calibration:",sum(chkcalib));
# fill time-dependent variables with calibration values
Cons = Cons0*onesrow(tend)
DG = DG0*onesrow(tend)
Inv = Inv0*onesrow(tend)
LD = LD0*onesrow(tend)
LS = LS0*onesrow(tend)
K = K0*onesrow(tend)
N = N0*onesrow(tend)
NB = NB0*onesrow(tend)
PB = PB0*onesrow(tend)
TFP = TFP0*onesrow(tend)
ab = ab0*onesrow(tend)
pc = pc0*onesrow(tend)
r = r0*onesrow(tend)
rag = rag0*onesrow(tend)
tauC = tauC0*onesrow(tend)
tauF = tauF0*onesrow(tend)
tauW = tauW0*onesrow(tend)
taul = taul0*onesrow(tend)
tauprof = tauprof0*onesrow(tend)
uck = uck0*onesrow(tend)
# fill time-dependent and age-dependent variables with calibration values
Av = kron(Av0, onesrow(tend))
Az = kron(Av0, onesrow(ncoh))
Consv = kron(Consv0, onesrow(tend))
Consz = kron(Consv0, onesrow(ncoh))
Nv = kron(Nv0, onesrow(tend))
Nz = kron(Nv0, onesrow(ncoh))
Savv = kron(Savv0, onesrow(tend))
Savz = kron(Savv0, onesrow(ncoh))
abv = kron(abv0, onesrow(tend))
abz = kron(abv0, onesrow(ncoh))
cGv = kron(cGv0, onesrow(tend))
cGz = kron(cGv0, onesrow(ncoh))
ellv = kron(ellv0, onesrow(tend))
ellz = kron(ellv0, onesrow(ncoh))
gamv = kron(gamv0, onesrow(tend))
gamz = kron(gamv0, onesrow(ncoh))
ivv = kron(ivv0, onesrow(tend))
ivz = kron(ivv0, onesrow(ncoh))
lambdav = kron(lambdav0, onesrow(tend))
lambdaz = kron(lambdav0, onesrow(ncoh))
notretv = kron(notretv0, onesrow(tend))
notretz = kron(notretv0, onesrow(ncoh))
pv = kron(pv0, onesrow(tend))
pz = kron(pv0, onesrow(ncoh))
tauCv = kron(tauCv0, onesrow(tend))
tauCz = kron(tauCv0, onesrow(ncoh))
tauWv = kron(tauWv0, onesrow(tend))
tauWz = kron(tauWv0, onesrow(ncoh))
taulv = kron(taulv0, onesrow(tend))
taulz = kron(taulv0, onesrow(ncoh))
thetav = kron(thetav0, onesrow(tend))
thetaz = kron(thetav0, onesrow(ncoh))
rv = kron(rv0, onesrow(tend))
rz = kron(rv0, onesrow(ncoh))
wv = kron(wv0, onesrow(tend))
wz = kron(wv0, onesrow(ncoh))
## some optional plots of the calibration
if genplots
plot(seq(0,nag-1), Av0, label = "", xlabel="age", ylabel="assets")
plot(seq(0,nag-1), Consv0, label = "consumption", xlabel = "age")
plot!(seq(0,nag-1), notretv0.*ellv0.*thetav0.*wv0.*(1.0.-tauWv0), label = "net labor income")
plot!(seq(0,nag-1), (1.0.-notretv0).*pv0.*(1.0.-tauWv0), label = "net pension income")
plot!(seq(0,nag-1), cGv0, label = "public consumption")
end
;