The Hamiltonian-based frequency formulation has been hailed as an unprecedented success for it gives a straightforward insight into a complex nonlinear vibration system with simple calculation. This paper gives a systematical analysis of the formulation, and two simplified formulations are suggested.  The cubic-quintic Duffing oscillator is used as an example to show extremely simple calculation and remarkable accuracy. It can be used as a paradigm for many other applications, and the one-step solving process has cleaned up the road of the nonlinear vibration theory. 

Rama G., Marinkovic D., Zehn M., 2018, High performance 3-node shell element for linear and geometrically nonlinear analysis of composite laminates, Composites Part B: Engineering, 151, pp. 118-126.

Wang, C.C., Yau, H.T., Jang, M.J., Yeh, Y.L., 2007, Theoretical analysis of the non-linear behavior of a flexible rotor supported by herringbone grooved gas journal bearings, Tribology International, 40(3), pp. 533–541.

Wang, C.C., Yau, H.T., 2008, Application of a hybrid numerical method to the bifurcation analysis of a rigid rotor supported by a spherical gas journal bearing system, Nonlinear Dynamics, 51(4), pp. 515–528.

Yau, H.T., 2008, Generalized projective chaos synchronization of gyroscope systems subjected to dead-zone nonlinear inputs, Physics Letters A, 372(14), pp. 2380-2385.

Yau, H.T., 2007, Nonlinear rule-based controller for chaos synchronization of two gyros with linear-plus-cubic damping, Chaos, Solitons and Fractals, 34(4), pp. 1357-1365.

Skrzypacz, P., Ellis, G., He, J.H., He, C.H., 2022, Dynamic pull-in and oscillations of current-carrying filaments in magnetic micro-electro-mechanical system, Communications in Nonlinear Science and Numerical Simulation, 109, 106350.

Tian, D., He, C.H., 2021, A fractal micro-electromechanical system and its pull-in stability, Journal of Low Frequency Noise, Vibration & Active Control, 40(3), pp. 1380-1386.

Ji, Q.P., Wang, J., Lu, L.X., Ge, C.F., 2021, Li-He's modified homotopy perturbation method coupled with the energy method for the dropping shock response of a tangent nonlinear packaging system, Journal of Low Frequency Noise, Vibration & Active Control, 40(2), pp. 675-682.

Shen, Y., El-Dib, Y.O., 2021, A periodic solution of the fractional Sine-Gordon equation arising in architectural engineering, Journal of Low Frequency Noise, Vibration & Active Control, 40(2), pp. 683-691.

Mitrev, R., Janošević, D., Marinković, D., 2017, Dynamical modelling of hydraulic excavator considered as a multibody system, Tehnicki Vjesnik, 24, pp. 327-338.

He, J.H., Amer, T.S., Elnaggar, S., Galal, A.A., 2021, Periodic Property and Instability of a Rotating Pendulum System, Axioms, 10(3), 191.

He, J.H., Amer, T.S., El-Kafly, H.F., Galal, A.A., 2022, Modelling of the rotational motion of 6-DOF rigid body according to the Bobylev-Steklov conditions, Results in Physics, 35(2022), 105391.

He, C.H., Tian, D., Moatimid, G.M., Salman, H.F., Zekry, M.H., 2022, Hybrid Rayleigh -Van der Pol-Duffing Oscillator: Stability Analysis and Controller, Journal of Low Frequency Noise, Vibration & Active Control, 41(1), pp. 244-268.

He, C.H., Amer, T.S., Tian, D., Abolila, A.F., Galal, A.A., 2022, Controlling the kinematics of a spring-pendulum system using an energy harvesting device, Journal of Low Frequency Noise, Vibration & Active Control, doi: 10.1177/14613484221077474.

Wang, K.L., Wei, C.F., 2021, A powerful and simple frequency formula to nonlinear fractal oscillators, Journal of Low Frequency Noise, Vibration & Active Control, 40(3), pp. 1373-1379.

Feng, G.Q., 2021, He's frequency formula to fractal undamped Duffing equation, Journal of Low Frequency Noise, Vibration & Active Control, 40(4), pp. 1671-1676.

Tian, Y., 2022, Frequency formula for a class of fractal vibration system, Reports in Mechanical Engineering, 3(1), pp. 55-61.

He, J.H., 2019, The simpler, the better: Analytical methods for nonlinear oscillators and fractional oscillators, Journal of Low Frequency Noise, Vibration & Active Control, 38(3–4), pp. 1252–1260.

He, J.H., El-Dib, Y.O., 2021, The enhanced homotopy perturbation method for axial vibration of strings, Facta Universitatis-Series Mechanical Engineering, 19(4), pp. 735-750.

He, J.H., El‐Dib, Y.O., Mady, A.A., 2021, Homotopy Perturbation Method for the Fractal Toda Oscillator, Fractal and Fractional, 5(2021), 93.

He, C.H., El-Dib, Y.O., 2022, A heuristic review on the homotopy perturbation method for non-conservative oscillators, Journal of Low Frequency Noise, Vibration & Active Control, doi: 10.1177/14613484211059264.

Nadeem, M., He, J.H., 2021, He-Laplace variational iteration method for solving the nonlinear equations arising in chemical kinetics and population dynamics, Journal of Mathematical Chemistry, 59(5), pp. 1234-1245.

Anjum, N., He, J.H., 2020, Analysis of nonlinear vibration of nano/microelectromechanical system switch induced by electromagnetic force under zero initial conditions, Alexandria Engineering Journal, 59(6), pp. 4343-4352.

Skrzypacz, P., He, J.H., Ellis, G., Kuanyshbay, M., 2020, A simple approximation of periodic solutions to microelectromechanical system model of oscillating parallel plate capacitor, Mathematical Methods in the Applied Science, DOI: 10.1002/mma.6898.

He, J.H., Hou W.F., Qie, N., Gepreel, K.A., Shirazi, A.H., Sedighi, H.M., 2021, Hamiltonian-based frequency-amplitude formulation for nonlinear oscillators, Facta Universitatis-Series Mechanical Engineering, 19(2), pp. 199-208.

He, J.H., 2006, Some asymptotic methods for strongly nonlinear equations, International Journal of Modern Physics b, 20(10), pp. 1141–1199.

Wang, K.J., Zhu, H.W., 2021, Periodic wave solution of the Kundu-Mukherjee-Naskar equation in birefringent fibers via the Hamiltonian-based algorithm, EPL, doi: 10.1209/0295-5075/ac3d6b.

Wang, K.J., Wang, G.D., 2022, Study on the nonlinear vibration of embedded carbon nanotube via the Hamiltonian-based method, Journal of Low Frequency Noise, Vibration & Active Control, 41(1), pp. 112-117.

He, C.H., Liu, C., 2022, A modified frequency-amplitude formulation for fractal vibration systems, Fractals, doi: 10.1142/S0218348X22500463.

He, J.H., El-Dib, Y.O., 2021, A tutorial introduction to the two-scale fractal calculus and its application to the fractal Zhiber-Shabat Oscillator, Fractals, 29(08), 2150268.

He, J.H., Yang, Q., He, C.H., Khan, Y., 2021, A Simple Frequency Formulation for the Tangent Oscillator, Axioms, 10, 320.

He, J.H., Qie, N., He, C.H., Gepreel, K., 2022, Fast identification of the pull-in voltage of a nano/micro-electromechanical system, Journal of Low Frequency Noise, Vibration & Active Control, 2022, doi: 10.1177/14613484211068252.

He, J.H., Hou, W.F., He, C.H., Saeed, T., Hayat, T., 2021, Variational approach to fractal solitary waves, Fractals, 29(07), 2150199.

He, C.H., 2016, An introduction to an ancient Chinese algorithm and its modification, International Journal of Numerical Methods for Heat & Fluid Flow, 26(8), pp. 2486-2491.

Khan, W.A., 2022, Numerical simulation of Chun-Hui He's iteration method with applications in engineering, International Journal of Numerical Methods for Heat & Fluid Flow, 32(3), pp. 944-955.