Abstract:
Economic recession has become a global and reccurring phenomenon which poses
worrisome uncertainties on assets’ returns in financial markets. Various stochastic
models have been formulated in response to price instability in financial markets.
However, the existing stochastic volatility models did not incorporate the concept of
economic recession and induced volatility-uncertainty for options price valuation in a
recessed economic setting. Therefore, this study was geared towards the formulation
of economic recession-induced stochastic models for price computation.
Stochastic modelling methods with probabilistic uncertainty measure were used to
formulate two new volatility models incorporating economy recession volatility uncertainties. The Feynman-Kac formula was applied to derive the characteristic functions for the two novel models. The derived characteristic functions were used to
obtain an inverse-Fourier analytic formula for European and American-style options. A modified Carr and Madan Fast-Fourier Transform (FFT)-algorithm was
used to obtain an approximate solution for the American-call option, and a class
of Multi-Assets option in multi-dimensions. Itˆo Calculus was used to obtain an
explicit formula for a Factorial function Black-Scholes Partial Differential Equations (BS-PDE) for American options subject to moving boundary conditions. The
FFT call-prices accuracy test at varied fineness grid points N was investigated using an FFT-algorithm via Maple, taking BS-prices as benchmark. Sample paths
and numerical simulations were generated via software codes for the control regimeswitching Triple Stochastic Volatility Heston-like (TSVH) model.
The derived Uncertain Affine Exponential-Jump Model (UAEM) with recession,
induced stochastic-volatility and stochastic-intensity, and a control regime-switching
Triple Stochastic Volatility Heston-like (TSVH) formulated with respect to economy
recession volatility uncertainties are:
d ln S(t) = r − q − λ(t)m dt + pσ(t)dWs(t) + (eν − 1)dN(t), S(0) = S0 > 0
dσ(t) = κσ β∗ + βrec − σ(t) dt + ξσpσ(t)dWσ(t), σ(0) = σ0 > 0
dλ(t) = κλθ − λ(t) dt + ξλpλ(t)dWλ(t), λ(0) = λ0 > 0.
and
dyt = r − q dt + pv1(t)dW1(t) + pv2(t)dW2(t) + αpv3(t)dW3(t) , S(0) = S0 > 0
dv1(t) = κ1θ1 − v1(t) dt + σ1pv1(t)dWc1(t), v1(0) = v10 > 0.
dv2(t) = κ2θ2 − v2(t) dt + σ2pv2(t)dWc2(t), v2(0) = v20 > 0.
dv3(t) = α κ3θ3 − v3(t) dt + σ3pv3(t)dWc3(t) recession, v3(0) = v30 > 0
respectively, where α was a binary control parameter defined as:
α := 0, if the economy is not in recession;
1, if the economy is in recession.
The inverse-Fourier analytic formulae for European-style and American-style calloptions obtained for the UAEM-process are:
Ecall
T (k) = exp(−αk)
π Z ∞
0
e−(rT +iuk)φτ u − (α + 1)i × α2 + α − u2 − i(2α + 1)u
α4 + 2α3 + α2 + 2(α2 + α) + 1 u2 + u4 du
ivand At(k) = exp(−αk)
π Z ∞
0
e−(rT +iuk) × φτu − (α + 1)i α2 + α − u2 − i(2α + 1)u
α4 + 2α3 + α2 + 2(α2 + α) + 1 u2 + u4 du + Pt,
respectively where Pt is premium price. The approximate solution obtained for American-call option via FFT-algorithm for the UAEM-process was:
A
τ (ku) ≈ exp(−αk)
π
NX j
=1
e−iuj ζη(j−1)(u−1) eiϖujψT (uj)η + Pt, where 1 ≤ u ≤ N and ζη = 2π
N
.
The derived multi-Assets options prices formula in n-dimension was:
VT (k1,p1, k2,p2 · · · , kn,pn) ≈ e−(α1k1,p1 +α2k2,p2 +...+αnkn,pn )
(2π)n Ω(k1,p1, k2,p2, · · · , kn,pn)
nY j
=1
hj,
where 0 ≤ p1, p2, · · · , pn ≤ N − 1 and
Ω(k1,p1, k2,p2, · · · , kn,pn) =
N1−1
X m1
=1
N1−1
X m2
=1
· · ·
N1−1
X
mn=1
e
−
2π
N (m1− N2 )(p1− N2 )+(m2− N2 )(p2− N2 )+···+(mn− N2 )(pn− N2 )
× ψT (u1, u2, · · · , un).
The derived explicit formula for the Factorial function BS-PDE was:
S(T) = S(t0) exp hn! r + 1 2(n − 1)σ2 T − t0 + n!σ W(t) − W(t0) i, S(t0) ̸= 0),
and the TSVH call pricing formula derived was:
C(K) = Ste−qτP1 − Ke−rτP2
such that
P1 = 1
2
+
1 π
Z ∞
0
ℜ exp(−iω ln K) fω − i; yt, v1(t), v2(t), v3(t)
iωSte(r−q)τ dω
P2 = 1
2
+
1 π
Z ∞
0
ℜ exp(−iω ln K) fω; yt, v1(t), v2(t), v3(t)
iω dω,
and fω − i; yt, v1(t), v2(t), v3(t) = exp A(τ, ω) + B0(τ, ω)yt + B1(τ, ω)v1(t) +
B2(τ, ω)v2(t) + B3(τ, ω)v3(t) where A, B0, B1, B2, B3 are coefficient terms of the
stochastic processes yt, v1(t), v2(t), v3(t).
The options prices obtained from An Uncertain Affine Exponential-Jump Model with
Recession, induced stochastic-volatility and stochastic-intensity and a control regimeswitching Triple Stochastic Volatility Heston-like model, were efficient in terms of
probable future payoffs and applicable in financial markets, for options valuation in
recessed and recession-free economy states.