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Samenvatting - Stochastic Calculus (6414M0013Y) $7.08   Add to cart

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Samenvatting - Stochastic Calculus (6414M0013Y)

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Comprehensive summary of the Stochastic Calculus course.

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  • September 27, 2024
  • 36
  • 2023/2024
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Derivative pricing in discrete time
Definitions & notations
-
Derivative: financial product defined from another underlying asset
· S
: price of underlying stock
·
: price of derivative (call)
C



te [0 T] : time ,




payoff: b(Si) b(S 1c[o ])
-

or e+ =
b =
+
, ,+




We will look at 3 main approaches to determine the price Ct



Replication
I




Risk-neutral valuation
2




3
Deflator valuation
But we first exploit some useful theory

The binary one-period model
Br S+ (u)
erT P



Bank Bo
Stock So
this are the underlying assets
ert 1-
p

Br S + (d)



example Bo =
1
,
e =
1 .
1
,
So =
100 ,
U =
1 .
25
,
d =
0 .
&
,
p
= 0 .
8



1 .
1 125 =
Sou
X 1.1
XU




Bank ↑
Stock 100

xd
X 1 . 1



1 . 80 = God




For these underlying assets we can work backwards when we know the value at t = 1, using discount factor erT

e E (S ] ( p))
*T *

So = e (Sou +p +
=
+ Sod + -




N



How can we now price the derivative using these underlying assets, Co ?
f(5 )
We can first calculate the payoff of the derivative using the underlying asset C+ = +




C+ (u) = &(Sou) =
e




lo


e+ (d) =
b(Sod) =
red




example max[Sou-k o],
=
max
[125 -
100
,
03 =
25




Payoff European call option & (S ) +
= max[S +
-

k ,
03 &



take strike price K = 100 max [Sod-k 03
,
=
max 200 -
100
,
03 =
0

, As said before there are three methods to derive this , let's look at the first one Co


I
Replication: find a portfolio strategy investing in the stock and a risk-free asset that matches the derivative
price at each point
notation




3
Portfolio:
E 0 = (4 0 , .
- 1)

-1 derivative (sell one unit of derivative)
7


&
Price Po 8 =
4 Bo + $50 -
Co

M



shares in stocks
>
R


N




invested in bonds P (w) (w)
>

Payoffs +
.
0 =
4B + + 03 + -
er



Price vector Pa ( (a)
~
=
,
St ,




An arbitrage is a portfolio with either
i) (w)
A negative price and a non-negative payoff in both states : 0 .
Po o
,
0 .
P+ Lo



ii) (c) 20 PLA (n) o]
A non-positive price and a non-negative payoff, positive in at least one state : 0 .

PoEo ,
0 .
P
+
,
.
P
+
< > o




N




We rule out arbitrage opportunities and impose law of one price: a portfolio with payoff zero has price zero:

S
& S (u)


S (d)
yB

+B
&
+




+
e (u)


(d)
hence we can find 0 4
+ + =




and use these to solve
+
+
=
+




C+ So ↑Bo hence find
.




&o = + Co



note the risky position St hedges the payoff, so that Ve-0SA BE is risk-free again
- =
4




28at
=at
i
-



N
note u =
d =
=
e




We can rewrite this to explicit solutions:

E
en-ed
*
↓ Son 4 Bo
↑ Boe +
O =

(= hedge ratio
en
:
Son-Sod
edu-end
A
) Co =
050
en-ed
+



edu-end
"T rT

& Sod ↓Boe"
-




↓ Bo


+
+ =
ed =
e u -
d u -
d


(
u - eT

ed u - d
, ,


g1-q

This q is the risk-neutral probability,
this brings us to the second method
&



2
Risk-neutral valuation: construct a risk neutral probability measure Q under which the derivative price
equals the Q-expected discounted payoffs
e T(eu (1 g)) e z(e ]
Hence we find g
2 = + + ed + -
=
+




note we do not use the p probabilities as this is irrelevant for Co




We could also exploit this idea to a market with N assets and n states, the risk-neutral measure can be
uniquely determined if N = n




Complete market: any derivative with payoff depending on underlying assets can be replicated
>




Incomplete markets: no-arbitrage still may provide bounds on derivate prices, which price is realized
depends on market risk preferences
7
this happens when , hence more states then underlying assetsn2 N

, Binomial tree
The binary model is not rich enough in practice, we need more states and time periods, we introduce the
binomial tree: series of binary trees
T


example N = 2 T note stock prices are recombinant, Sc(nd) Sc(du), derivative price tree might be not
at = =




So un en (nu)
W W



Son & (u)
U U
d d


Stocks So So du (nd) (du)
U
Soud :

Call Co

d
U
en :
en

d


2
God C . (d)
At

d d

Sodd en(dd)




3
Using these binomial tree, we can calculate Co using backward pricing
step 1: calculate the payoffs at time N f (Sn- u) or &(Swd) :
,




step 2: using these payoffs and q, calculate en-1 e E [en /Sn ] et[ein /Si]
*
=
-1
In summary, li =




ere[en- /Sn-2]
r(N i) at
Ea[enISi]
-




step 3: repeat
-




&w - z =

or Ci = e




step 4: work backwards until Co




When we know all the derivative values, we also know all the hedging values
Miti (u) -
Citi (d) u(i +,
(d) -
dCi +
(u)


Di + 1
=
Sin-Sid Nit Bi ,
=
grat u -
d


This sequence (i + 1
,
Pi +
1) is a dynamic portfolio strategy with:
#




I




P




intermezzo: discrete-time martingales
definitions
·
probability space (r .
F ,
P)
>
probability measure I : gives probability to events in F ex. P(A) =
cp(i p)
-




collection of events A ex. F contains A End Y and A Sun da]
-field F : -l :

,
du =
,




sample space : set of all possible outcomes 7
ex. Enu dd] R wel 2 :
,
ud ,
du ,




random variable
X , assigns real numbers to outcomes
R : 1 >




R , random variable with extra dimension
stochastic variable : 2xT
~ >




example the variable Xt , takes 3 different values at t =
0 .
6



each corresponds to one sample path/trajectory W




Xe(w) is a collection of random variables, defined in one common probability space

, Y




the --field lists all events that might happen to X
F


7
we can define smaller O-fields Fr , collecting events that might have happened before n
>
filtration · [0 23 .
:
Fo F E .
. . .
[Fr ( : 5)

example 1 : Sunu ,
nud ,
udu ,
udd ,
dun ,
dud ,
du ,
Add 3

A: Eunu ,
und ,
uda ,
add 3 cr



F. : [0 ,
r ,
A , A ,
3]

In X" ((x3) [w X(w) Ye Fr( (B) (w X(w) BYE
·
measurability: = = = x
for continuous X = : = Fr


when this holds for all n, then Xr is adapted to the filtration Fr
&




I




ex. -fields Fr is the information set then the conditions 'X is G-measurable says 'the information set G I



S




contains X , and HEG is interpreted as 'all information in I is contained in G

important properties expected values
remember E(X) x(wi)p(wi) E(X1B) = X(wi) P(wilB) :
·




for finite field GEF E(XIG) (w) E(X/aw) An MStieg
· -
: = =
: we Ail

·
E(X1g) : X
if X is G-measurable
· E(X 150) : E(X)

·
E(XY(g) =

XE(y(g) if X
is G-measurable
·
EZE(Xig)] :
E(X)

5
E[E(X(g)(2] :
E(X (2) 288 = 5
(tower property)
>

ex. ELE(XIFn)IFn] E(XIFn) En E(X(fn) E(XIXo Xn)
if is generated by X, then
:


,
=
,
X , .
. .
.,




martingales
Xn
is a martingale with respect to In and I if: A stochastic process is said to have the


]
Xr
is adapted to In each Xn is measurable with respect to ,
= martingale property if, at any given time, the
expected value of the future values of the
-EP((Xn)) < process, conditional on the information
available up to the present time, is equal to
3E(Xn + 1 15n) : Xn
the current value.
example E(Xn + 1
15n) =
ELE(X1fn 1) (5n] +
:
E[X1Fn] :
Xn




martingale transform
when Xn is a (P Fn) -martingale, and .
on
is previsable ( On is Fn-measurable) . then In = 20 + "Pin (Xin -Xi) is also a
(P Fr) martingale
.

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