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CPS 196.2 Securities & Expressive Securities Markets Vincent Conitzer

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1 CPS 196.2 Securities & Expressive Securities Markets Vincent Conitzer conitzer@cs.duke.edu

2 Call options A (European) call option C(S, k, t) gives you the right to buy stock S at (strike) price k on (expiry) date t –American call option can be exercised early –European one easier to analyze How much is a call option worth at time t (as a function of the price of the stock)? k p t (S) value p t (C)

3 Put options A (European) put option P(S, k, t) gives you the right to sell stock S at (strike) price k on (expiry) date t How much is a put option worth at time t (as a function of the price of the stock)? k p t (S) value p t (P)

4 Bonds A bond B(k, t) pays off k at time t k p t (S) value p t (B)

5 Stocks k p t (S) value p t (S)

6 Selling a stock (short) k p t (S) value -p t (S)

7 A portfolio k p t (S) value One call option C(S, k, t) + one bond B(k, t) k

8 Another portfolio k p t (S) value One put option P(S, k, t) + one stock S k same thing!

9 Put-call parity C(S, k, t) + B(k, t) will have the same value at time t as P(S, k, t) + S (regardless of the value of S) Assume stocks pay no dividends Then, portfolio should have the same value at any time before t as well I.e. for any t’ < t, it should be that p t’ (C(S, k, t)) + p t’ (B(k, t)) = p t’ (P(S, k, t)) + p t’ (S) Arbitrage argument: suppose (say) p t’ (C(S, k, t)) + p t’ (B(k, t)) < p t’ (P(S, k, t)) + p t’ (S) Then: buy C(S, k, t) + B(k, t), sell (short) P(S, k, t) + S Value of portfolio at time t is 0 Guaranteed profit!

10 Another perspective: auctioneer Auctioneer receives buy and sell offers, has to choose which to accept E.g.: offers received: buy(S, $10); sell(S, $9) Auctioneer can accept both offers, profit of $1 E.g. (put-call parity): –sell(C(S, k, t), $3) –sell(B(k, t), $4) –buy(P(S, k, t), $5) –buy(S, $4) Can accept all offers at no risk!

11 “Butterfly” portfolio 1 call at strike price k-c -2 calls at strike k 1 call at strike k+c c p t (S) value kk-ck+c

12 Another portfolio Can we create this portfolio? p t (S) value

13 Yet another portfolio How about this one? p t (S) value

14 Two different stocks A portfolio with C(S 1, k, t) and S 2 p t (S 1 ) p t (S 2 ) k isovalue curves k+ak+b a b a b

15 Another portfolio Can we create this portfolio? (In effect, a call option on S 1 +S 2 ) p t (S 1 ) p t (S 2 ) k k+ak+b k 0 k+a k+b a b

16 A useful property Suppose your portfolio pays off f(p t (S 1 ), p t (S 2 )) = f 1 (p t (S 1 )) + f 2 (p t (S 2 )) (additive decomposition over stocks) This is all we know how to do Then: f(x 1, x 2 ) - f(x 1, x 2 ’) = f(x 1 ) + f(x 2 ) - f(x 1 ) - f(x 2 ’) = f(x 2 ) - f(x 2 ’) = f(x 1 ’, x 2 ) - f(x 1 ’, x 2 ’)

17 Portfolio revisited Can we create this portfolio? (In effect, a call option on S 1 +S 2 ) p t (S 1 ) p t (S 2 ) k k+ak+b k 0 k+a k+b a b x1’x1’ x1x1 x2x2 x2’x2’ f(x 1, x 2 ) - f(x 1, x 2 ’) ≠ f(x 1 ’, x 2 ) - f(x 1 ’, x 2 ’) Impossible to create this portfolio with securities that only refer to a single stock!

18 Securities conditioned on finite set of outcomes E.g. InTrade: security that pays off 1 if Clinton wins Democratic nomination, 0 otherwise Can we construct a portfolio that pays off 1 if Clinton wins Democratic nomination AND Giuliani wins Republican nomination? Giuliani loses Giuliani wins Clinton loses$0 Clinton wins$0$1

19 Arrow-Debreu securities Suppose S is the set of all states that the world can be in tomorrow For each s in S, there is a corresponding Arrow- Debreu security that pays off 1 if s happens, 0 otherwise E.g. s could be: Clinton wins nomination and Giuliani loses nomination and S 1 is at $4 and S 2 at $5 and butterfly 432123 flaps its wings in Peru and… Not practical, but conceptually useful Can think about Arrow-Debreu securities within a domain (e.g. states only involve stock trading prices) Practical for small number of states

20 With Arrow-Debreu securities you can do anything… Suppose you want to receive $6 in state 1, $8 in state 2, $25 in state 3 … simply buy 6 AD securities for state 1, 8 for state 2, 25 for state 3 Linear algebra: Arrow-Debreu securities are a basis for the space of all possible securities

21 The auctioneer problem Tomorrow there must be one of Agent 1 offers $5 for a security that pays off $10 if or Agent 3 offers $6 for a security that pays off $10 if Agent 2 offers $8 for a security that pays off $10 if or Can we accept some of these at offers at no risk?

22 Reducing auctioneer problem to ~combinatorial exchange winner determination problem Let (x, y, z) denote payout under,,, respectively Previous problem’s bids: –5 for (0, 10, 10) –8 for (10, 0, 10) –6 for (10, 0, 0) Equivalently: –(-5, 5, 5) –(2, -8, 2) –(4, -6, -6) Sum of accepted bids should be (≤0, ≤0, ≤0) to have no risk Sometimes possible to partially accept bids

23 A bigger instance (4 states) Objective: maximize our worst-case profit 3 for (0, 0, 11, 0) 4 for (0, 2, 0, 8) 5 for (9, 9, 0, 0) 3 for (6, 0, 0, 6) 1 for (0, 0, 0, 10) What if they are partially acceptable?

24 Settings with large state spaces Large = exponentially large –Too many to write down Examples: S = S 1 x S 2 x … S n –E.g. S 1 = {Clinton loses, Clinton wins}, S 2 = {Giuliani loses, Giuliani wins}, S = {(Cl, Gl), (Cl, Gw), (Cw, Gl), (Cw, Gw)} –If all S i have the same size k, there are k n different states S is the set of all rankings of n candidates –E.g. outcomes of a horse race –n! different states (assuming no ties)

25 Bidding languages How should trader (bidder) express preferences? Logical bidding languages [Fortnow et al. 2004] : –(1) “If Clinton wins OR (Giuliani wins AND Obama wins), I want to receive $10; I’m willing to pay $6 for this.” If the state is a ranking [Chen et al. 2007] : –(2a) “If horse A ranks 2 nd, 3 rd, or 4 th I want to receive $10; I’m willing to pay $6 for this.” –(2b) “If one of horses A, C, D rank 2 nd, I want to receive $10; I’m willing to pay $6 for this.” –(2c) “If horse A ranks ahead of horse C, I want to receive $10; I’m willing to pay $6 for this.” Winner determination problem is NP-hard for all of these, except for (2a) and (2b) which are in P if bids can be partially accepted

26 A different computational problem closely related to (separation problem for) winner determination Given that the auctioneer has accepted some bids, what is the worst-case outcome (state) for the auctioneer? For example: Must pay 2 to trader A if horse X or Z is first Must pay 3 to trader B if horse Y is first or second Must pay 6 to trader C if horse Z is second or third Must pay 5 to trader D if horse X or Y is third Must pay 1 to trader E if horse X or Z is second

27 Reduction to weighted bipartite matching Must pay 2 to trader A if horse X or Z is first Must pay 3 to trader B if horse Y is first or second Must pay 6 to trader C if horse Z is second or third Must pay 5 to trader D if horse X or Y is third Must pay 1 to trader E if horse X or Z is second 2 1 5 3 3 5 6 6 2 X Y Z 3 2 1 7

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