Difference between revisions of "VC Bargaining"
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:<math> \frac{\partial V_2}{\partial x_1} =0 \implies x_1 = x_2 = \frac{1}{2}\,</math> | :<math> \frac{\partial V_2}{\partial x_1} =0 \implies x_1 = x_2 = \frac{1}{2}\,</math> | ||
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| + | \therefore V_2 = \frac{1}{2}^\frac{1}{2} + \frac{1}{2}^\frac{1}{2} = 1^\frac{1}{2} \approx 1.41 | ||
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| + | How much should be allocated to the investor? | ||
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| + | Using Shapley values, Nash Bargaining and infinite Rubenstein bargaining will all imply each party gets \frac{1}{2}^\frac{1}{2}\approx 0.707, assuming equal outside options of zero and equal bargaining power. | ||
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| + | Proof using the Shapley value for a single stage of negotiation: | ||
| + | |||
| + | V(C | ||
Revision as of 21:54, 25 May 2011
This page (and the discussion page) is for Ed and Ron to share their thoughts on VC Bargaining. Access is restricted to those with "Trusted" access.
Contents
A Basic Model
The players
The players are an Entrepreneur and a VC, both are risk neutral.
The Value Function
- [math]V_t=V_{t-1} + f(x_t) - k \,[/math]
with
- [math]V_0=0, f(0)=0, f'\gt 0, f''\lt 0, k\gt 0 \,[/math]
Having [math]k\gt 0\,[/math] forces a finite number of rounds as the optimal solution providing there is a stopping constraint on [math]V_t\,[/math] (so players don't invest forever).
One possible stopping constraint is:
- [math]V_t \ge \overline{V}\,[/math]
with
- [math]\overline{V} \sim F(V)\,[/math]
where the distribution is known to both parties.
Bargaining
In each period there is Rubenstein finite bargaining, with potentially different patience, and one player designated as last. This will give a single period equilibrium outcome with the parties having different bargaining strength.
Simple First Steps
Address the question: How does the optimal policy compare to the current way of calculating shares and values?
Assume a fixed number of rounds: [math]t={1,2}\,[/math] Assume a fixed total investment: [math]\sum_t x_t = 1\,[/math] Assume a functional form for [math]f(x_t): f(x_t) = x_t^\frac{1}{2}\,[/math]
Again [math] V(0)=0 \,[/math].
- [math] \therefore V_2 = x_1^\frac{1}{2} + x_2^\frac{1}{2}\,[/math]
Recalling that [math] x_2 = 1 - x_1 \,[/math]
- [math] \frac{\partial V_2}{\partial x_1} =0 \implies x_1 = x_2 = \frac{1}{2}\,[/math]
\therefore V_2 = \frac{1}{2}^\frac{1}{2} + \frac{1}{2}^\frac{1}{2} = 1^\frac{1}{2} \approx 1.41
How much should be allocated to the investor?
Using Shapley values, Nash Bargaining and infinite Rubenstein bargaining will all imply each party gets \frac{1}{2}^\frac{1}{2}\approx 0.707, assuming equal outside options of zero and equal bargaining power.
Proof using the Shapley value for a single stage of negotiation:
V(C
