Loss-Versus-Rebalancing under Deterministic and Generalized block-times

Abstract

Although modern blockchains almost universally produce blocks at fixed intervals, existing models still lack an analytical formula for the loss-versus-rebalancing (LVR) incurred by Automated Market Makers (AMMs) liquidity providers in this setting. Leveraging tools from random walk theory, we derive the following closed-form approximation for the per block per unit of liquidity expected LVR under constant block time: \[ ARB= \,σb2 \,2+2π\,γ/(|ζ(1/2)|\,σb)\,+O\!(e-constγσb)\;≈\; σb2\,2 + 1.7164\,γ/σb, \] where σb is the intra-block asset volatility, γ the AMM spread and ζ the Riemann Zeta function. Our large Monte Carlo simulations show that this formula is in fact quasi-exact across practical parameter ranges. Extending our analysis to arbitrary block-time distributions as well, we demonstrate both that--under every admissible inter-block law--the probability that a block carries an arbitrage trade converges to a universal limit, and that only constant block spacing attains the asymptotically minimal LVR. This shows that constant block intervals provide the best possible protection against arbitrage for liquidity providers.