Perovskites　and　graphene　are　receiving　a　meteoric　rise　in　popularity　in　the　field　of　active　photonics　because　they　exhibit　excellent　optoelectronic　properties　for　dynamic　manipulation　of　light-matter　interactions.　However,　challenges　still　exist,　such　as　the　instability　of　perovskites　under　ambient　conditions　and　the　low　Fermi　level　of　graphene　in　experiments.　These　short-　comings　limit　the　scope　of　applications　when　they　are　used　alone　in　advanced　optical　devices.　However,　the　combination　of　graphene　and　perovskites　is　still　a　promising　route　for　efficient　control　of　light-matter　interactions.　Here,　we　report　a　dual-optoelectronic　metadevice　fabricated　by　integrating　terahertz　metasurfaces　with　a　sandwich　complex　composed　of　graphene,　polyimide,　and　perovskites　for　ultra-wideband　and　multidimensional　manipulation　of　higher-order　Fano　resonances.　Owing　to　the　photogenerated　carriers　and　electrostatic　doping　effect,　the　dual　optoelectronic　metadevice　showed　different　manipulation　behavior　at　thermal　imbalance　(electrostatic　doping　state　of　the　system).　The　modulation　depth　of　the　transmission　amplitude　reached　200%,　the　total　resonant　frequency　shift　was　800　GHz,　and　the　tunable　range　of　the　resonant　frequency　was　68.8%.　In　addition,　modulation　of　the　maximum　phase　reached　346　degrees.　This　work　will　inspire　a　new　generation　of　metasurface-based　optical　devices　that　combine　two　active　materials.