The trading strategy of `buy-and-hold for superior stock and
sell-at-once for inferior stock', as suggested by conventional
wisdom, has long been prevalent in Wall Street. In this paper, two
rationales are provided to support this trading strategy from a
purely mathematical standpoint. Adopting the standard binomial
tree model (or CRR model for short, as first introduced in Cox,
Ross and Rubinstein (1979)) to model the stock price dynamics, we
look for the optimal stock selling rule(s) so as to maximize
(i) the chance that an investor can sell a stock precisely at its
ultimate highest price over a fixed investment horizon [0,T];
and (ii) the expected ratio of the selling price of a stock to its
ultimate highest price over [0,T].
We show that both problems have exactly the same
optimal solution which can literally be interpreted as `buy-and-hold or
sell-at-once' depending on the value of p (the going-up probability of
the stock price at each step):
when p›½, selling the stock at
the last time step $N$ is the optimal selling strategy; when
p=½, a selling time is optimal if the stock is sold
either at the last time step or at the time step when the stock
price reaches its running maximum price; and when p‹½,
time 0, i.e. selling the stock at once, is the unique optimal
selling time.
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