This　paper　proposes　a　distance-independent　wireless　charging　system　that　achieves　constant　current　(CC)　and　constant　voltage　(CV)　output　through　utilization　of　a　reconfigurable　topology,　capable　of　seamlessly　switching　between　a　two-coil　and　a　three-coil　configuration.　In　order　to　enhance　output　adjustability　and　improve　the　efficiency　of　the　charging　process,　this　system　combines　the　advantages　of　fractional-order　and　integer-order　resonant　circuits.　In　the　two-coil　configuration,　the　output　of　the　inverter　on　the　transmitter　side　is　modulated　as　that　of　a　fractional-order　capacitor.　By　analyzing　frequency　characteristics　of　the　fractional-order　circuit,　a　control　strategy　of　variable　fractional　order　is　introduced　to　achieve　CC　output　against　variations　of　transfer　distance　based　on　a　mutual　inductance　recognition　method.　After　transitioning　to　the　three-coil　configuration,　the　system　inherently　achieves　a　CV　output　by　operating　the　inverter　at　a　fixed　frequency　and　forming　an　integer-order　resonant　circuit.　In　addition,　in　both　mentioned　configurations,　the　full-bridge　(FB)　mode　and　half-bridge　(HB)　mode　of　the　inverter　are　utilized　to　minimize　switching　losses　and　broaden　the　range　of　soft-switching　operation,　catering　to　various　load　conditions.　Finally,　an　experimental　prototype　is　built　to　achieve　CC　and　CV　output　within　a　wide　charging　range.