Tuesday, October 11, 2016

Should I use math or just assume convergence of a vague algorithm?



Arnold Kling apparently doesn't think math is necessary (H/T Noah Smith):
Think of [recent Nobel winners Hart and Holmstrom's] work as consisting of three steps.

1. Identifying some real-world complexities that affect how businesses operate. ...
2. Construct a mathematical optimization model that incorporates such complexities.
3. Offer insights into designing appropriate compensation systems, including when to outsource an activity altogether.
...
In my view, step 2 is unnecessary.
Tell us what you really think:
But I do not think in terms of mathematical optimization. Instead, I think in terms of a dynamic process of trial and error. A manager tries an approach to compensation. As long as it seems to work, it persists. 
So exploring the compensation strategy space by trial and error, a manager determines if a given strategy meets his or her objective. Or another way, by randomly sampling the compensation domain and evaluating some objective function, the manager arrives at an optimal solution. Of course. That is not thinking in terms of mathematical optimization at all. It is completely different! Wait (wikipedia):
In evolutionary computation, differential evolution (DE) is a method that optimizes a problem by iteratively trying to improve a candidate solution with regard to a given measure of quality. Such methods are commonly known as metaheuristics as they make few or no assumptions about the problem being optimized and can search very large spaces of candidate solutions. However, metaheuristics such as DE do not guarantee an optimal solution is ever found.
Joking aside, it's the last sentence that the math is good for. Like many optimization methods, there is no guarantee that an optimal solution can be found. Does Kling's "dynamic process of trial and error" converge to any solution? You can't just 'reckon' the location of the optimum and the path to it that can be discovered by agents. Sure, you can give the intuition of that process, but an explicit example using mathematical optimization gives me confidence in your eyeballed solution and assumed convergence.

[update + 30 min] The real function of math isn't to arrive at your intuition for a problem. It can for people who's minds work that way, but I generally visualize things in a way not entirely unlike Kling -- usually in pictures that only eventually become more rigorous like here or here or here (that last one is behind the sketch I turned into the favicon for this blog). The real function of math is to convince others who can't see your mental process (instead of Kling's manager, I saw a person exploring a diagram like the one at the top of this post), and to make sure your imagination dots the i's and crosses the t's (e.g. convergence or existence).

2 comments:

  1. At least as far as headlines go, this seems a somewhat unfair read on Kling; his point is that most economic agents aren't rational omniscient optimizers, and making that the focus of economic research is perhaps unwise. Better to assume they are local optimizers, at best.

    This seems quite reasonable as a point, and in have no idea if it is fair to the Nobelists being discussed.

    A far more interesting question is whether the state spaces in question are reasonably optimized by a sort of 'managerial gradient decent'. If so, then the choice of (complex) math or heuristic is irrelevant to the final state.

    Bp

    ReplyDelete
    Replies
    1. I re-read Kling's piece and it seems to be about the use of math. Mentioned in every single paragraph.

      He also isn't doubting the conclusions of the Nobelists' work -- his primary point is that he thinks he could arrive at them without using math.

      A far more interesting question is whether the state spaces in question are reasonably optimized by a sort of 'managerial gradient decent'. If so, then the choice of (complex) math or heuristic is irrelevant to the final state.

      The first part is exactly my point (Kling's intuition can be expressed mathematically), however I disagree with the second sentence. Different algorithms will have different results. Some equilibria are "learnable" so how you achieve them is directly linked to the final state.

      Delete

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