This　paper　discusses　the　design　of　a　metasurface　with　low　radar　cross-section　(RCS)　property.　Three　different　configurations　of　metasurface　including　chessboard-like　configuration,　triangular-shaped　configuration,　and　optimized　configuration,　with　the　help　of　artificial　magnetic　conductor　(AMC)　unit　cells,　are　designed　to　construct　the　low　scattering　surface.　Two　different　AMC　unit　cells　with　180°　±　37°　phase　difference　are　designed　to　obtain　the　out　of　phase　reflection　in　a　wide　frequency　band.　Then,　these　AMC　unit　cells　are　employed　into　different　configurations　to　study　the　RCS　reduction　bandwidth.　The　simulated　results　show　that　the　chessboard-like　metasurface　and　triangular-shaped　metasurface　redirect　the　incident　electromagnetic　energy　into　four　and　eight　scattering　lobes　away　from　the　normal　direction.　Due　to　the　more　scattering　lobes,　the　triangular-shaped　metasurface　exhibits　a　wide　10dB　RCS　reduction　bandwidth.　To　further　widen　the　RCS　reduction　bandwidth,　the　placements　of　the　AMC　unit　cell　are　further　optimized　using　a　genetic　algorithm　to　construct　the　optimized　metasurface.　The　designed　optimized　metasurface　diffuses　the　scattering　lobes　with　less　scattering　amplitude　in　the　normal　direction.　This　investigation　explains　that　the　optimized　metasurface　shows　a　wide　10　dB　RCS　reduction　bandwidth　as　compared　to　the　chessboard-like　configuration　and　triangular-shaped　configuration.　To　further　validate　the　RCS　reduction　performance　of　the　metasurfaces,　the　bistatic　RCS　analysis　of　the　chessboard-like　surface,　triangular-shaped　surface,　and　optimized　metasurface　is　presented　and　compared　with　the　metallic　plate.　The　analysis　shows　that　the　designed　metasurface　show　an　obvious　RCS　reduction　as　compared　to　the　reference　metallic　plate　in　the　monostatic　and　bistatic　configuration.　Therefore,　the　designed　metasurfaces　can　be　utilized　in　the　stealth　platforms　where　low　observability　of　the　surfaces　is　required.　©　2019　IEEE.