Method for configuring an electronic device having an inductive receiver coil with ultra-thin shielding layer

The invention claimed is: 1. A method for configuring an electronic device for being inductively powered or charged, comprising: configuring an inductive receiver coil for generating current in response to being exposed to an alternating magnetic field generated substantially on a first side of the inductive receiver coil; and disposing an ultra-thin soft magnetic shielding layer, comprising a thickness less than or equal to one hundred micrometers (100 μm), on a second side of the inductive receiver coil, opposite to the first side where the magnetic field is generated, the soft magnetic shielding layer configured to mitigate formation of eddy currents within the shielding layer and an overlying object wherein forming within the soft magnetic shielding layer, via laser cutting, a plurality of slits substantially parallel to magnetic flux lines and orthogonal to eddy current flow, wherein the soft magnetic shielding material is attached to a transparent adhesive foil, and laser energy is directed towards the soft magnetic shielding material layer at desired sites to evaporate corresponding soft magnetic shielding material to form the slits, wherein the transparent adhesive foil remains intact, said slits configured to impose a large impedance to eddy current formation extending from an outer perimeter of the shielding layer toward a middle region of the shielding layer, wherein the middle region comprises: a material selected from a group consisting of: Mumetal, nanocristaline metal and amorphous metals and the slits are not present in the middle region. 2. The method of claim 1 , wherein a total thickness of the inductive receiver coil and the ultra-thin soft magnetic shielding layer is than 300 μm. 3. The method of claim 1 , wherein the overlying object comprises an object selected from a group consisting of: a rechargeable battery with a conductive housing, an electronic circuit and a lamp module with a metallic base plate, further wherein the metallic base plate of the lamp module is configured for being disposed overlying the shielding layer, the lamp for being powered in response to the generated current.