This　research　aims　to　investigate　the　nonlinear　vibration　of　the　in-plane　bi-directional　functionally　graded　(BDFG)　plate　with　global　and　localized　geometrical　imperfection　subjected　to　a　transverse　harmonic　excitation.　The　material　properties　of　plate　are　varying　along　two　in-plane　directions.　The　global　and　localized　geometrical　imperfections　are　simulated　in　the　form　of　products　of　trigonometric　and　hyperbolic　functions.　Based　on　the　von　K　&　aacute;rm　&　aacute;n＇s　nonlinear　plate　theory,　coupled　nonlinear　partial　differential　equations　governing　in-plane　and　transverse　displacements　of　BDFG　plate　are　derived　employing　Hamilton＇s　principle.　The　continuous　nonlinear　model　of　imperfect　BDFG　plate　is　discretized　using　the　Galerkin　scheme,　resulting　in　the　reduced　order　model.　The　pseudo-arclength　continuation　technique　is　employed　to　trace　the　periodic　motion　of　plate　and　construct　frequency　/force-response　curves.　Dynamic　responses　are　solved　using　numerical　integration.　Numerical　results　of　ceramic-metal　BDFG　plates　are　presented　to　examine　the　effects　of　system　parameters,　e.g.　functional　gradient　parameters,　external　excitation　parameters　and　damping　coefficients.　Particularly,　influences　of　global　and　localized　geometrical　imperfections　are　highlighted.　Results　show　that　the　variation　of　gradient　parameter　and　the　existence　of　geometrical　imperfection　change　the　nonlinearity　of　resonant　response.　Cyclic-fold,　period　doubling　and　torus　bifurcations　of　the　periodic　solution　are　detected　as　excitation　parameters　varying.　Periodic,　quasi-periodic　and　chaotic　motions　of　plate　are　also　explored.　(c)　2021　Elsevier　Inc.　All　rights　reserved.