Concurrent learning (CL) is a recently developed adaptive update scheme that can be used to guarantee parameter convergence without requiring persistent excitation. However, this technique requires knowledge of state derivatives, which are usually not directly sensed and therefore must be estimated. A novel integral CL method is developed in this paper that removes the need to estimate state derivatives while maintaining parameter convergence properties. Data recorded online is exploited in the adaptive update law, and numerical integration is used to circumvent the need for state derivatives. The novel adaptive update law results in negative definite parameter error terms in the Lyapunov analysis, provided an online-verifiable finite excitation condition is satisfied. A Monte Carlo simulation illustrates improved robustness to noise compared to the traditional derivative formulation. The result is also extended to Euler-Lagrange systems, and simulations on a two-link planar robot demonstrate the improved performance compared to gradient-based adaptation laws. PARIKH ET AL. verified online, in general, for nonlinear systems. However, all current CL methods require that the output data include the state derivatives, which may not be available for all systems. Since the naive approach of finite difference of the state measurements leads to noise amplification, and since only past recorded data, opposed to real-time data, is needed for CL, techniques such as online state derivative estimation or smoothing have been employed, eg, the works of Mühlegg et al 9 and Kamalapurkar et al. 10 However, these methods typically require tuning parameters such as an observer gain and switching threshold in the case of the online derivative estimator and basis, basis order, covariance, and time window in the case of smoothing, to produce satisfactory results.In this note, we reformulate the derivative-based CL method (DCL) in terms of an integral, removing the need to estimate state derivatives. Other methods such as composite adaptive control also use integration-based terms to improve parameter convergence (see, eg, the works of Slotine and Li, 11 Volyanskyy et al, 12 and Pan et al 13 ); however, they still require PE to ensure exponential convergence. Recently, results in other works 14-18 have shown convergence using an interval or finite excitation condition, although they either require measurements of state derivatives (see, eg, the work of Pan and Yu 15 ), require determining the analytical Jacobian of the regressor (see, eg, the work of Pan et al 14 ), or are developed in a model reference adaptive control context, 16,17,[19][20][21] which essentially assume that desired trajectories are generated from an LTI system and may rely on a matching condition, rather than the general nonlinear systems considered here without such assumptions. Some results 22-27 have theoretical analogs to those presented here, and some use filtering techniques to avoid data storage requirements, although we show how the parameter estimation i...
