Abstract
Financial markets exhibit a complex hierarchy among different processes, e.g. a trading time marks the initiation of a trade, and a trade triggers a price change. High-frequency trading data arrive at random times. By combining stochastic and agent-based approaches, we develop a model for trading time, trading volume, and price changes. We generate intertrade time (time between successive trades) Δt
i
, and the number of shares traded q(Δt
i
) as two independent but power-law autocorrelated processes, where Δt
i
is subordinated to q(Δt
i
), and Δt
i
is more strongly correlated than q(Δt
i
). These two power-law autocorrelated processes are responsible for the emergence of strong power-law correlations in (a) the total number of shares traded N(ΔT) and (b) the share volume Q
ΔT
calculated as the sum of the number of shares q
i
traded in a fixed time interval ΔT. We find that even though q(Δt
i
) is weakly power-law correlated, due to strong power-law correlations in Δt
i
, the (integrated) share volume exhibits strong long-range power-law correlations. We propose that intertrade times and bid–ask price changes share the same volatility mechanism, yielding the power-law autocorrelations in absolute values of price change and power-law tails in the distribution of price changes. The model generates the log-linear functional relationship between the average bid–ask spread ⟨S⟩ΔT
and the number of trade occurrences N
ΔT
, and between ⟨S⟩ΔT
and Q
ΔT
. We find that both results agree with empirical findings.
Acknowledgements
We thank the Ministry of Science of Croatia, the Keck Foundation Future Initiatives Program, and NSF grants PHY-0855453, CMMI-1125290, CHE-0911389, and CHE-0908218 for financial support.