Magnetic device with high saturation current and low core loss

What is claimed is: 1. A magnetic device comprising: a T-shaped magnetic core including a base and a pillar, the base having a first surface and a second surface opposite to the first surface, the pillar being located on the first surface of the base, the second surface of the base being exposed to outer environment as an outer surface of the magnetic device, the T-shaped magnetic core being made of an annealed soft magnetic metal material, a core loss P CL (mW/cm 3 ) of the T-shaped magnetic core satisfying: 0.64 ×f 0.95 ×B m 2.20 ≦P CL ≦7.26 ×f 1.41 ×B m 1.08 , where f (kHz) represents a frequency of a magnetic field applied to the T-shaped magnetic core, and B m (kGauss) represents the operating magnetic flux density of the magnetic field at the frequency; a wire coil surrounding the pillar, the wire coil having two leads; and a magnetic body fully covering the pillar, any part of the base that is located above the second surface of the base, and any part of the wire coil that is located directly above the first surface of the base, wherein a volume V1 of the base and a volume V2 of the pillar satisfies: V1/V2≦2.093. 2. The magnetic device of claim 1 , wherein the two leads of the wire coil are respectively connected to two electrodes on the base. 3. The magnetic device of claim 1 , wherein the magnetic body fully covers any part of the wire coil that is located above the first surface of the base. 4. The magnetic device of claim 1 , wherein the two electrodes are embedded in the base. 5. The magnetic device of claim 4 , wherein a bottom surface of each of the two electrodes is substantially coplanar with the second surface of the base, and a lateral surface of each of the two electrodes is substantially coplanar with a corresponding one of two opposite lateral surfaces of the base. 6. The magnetic device of claim 1 , wherein the base has two recesses respectively located on two lateral sides of the base, the two recesses respectively receiving the two leads so that the two leads are respectively in contact with the two electrodes via the two recesses. 7. The magnetic device of claim 1 , wherein the base is a rectangular base with right-angled corners or curved corners, and a shortest distance from each of the four ends of the rectangular base to the pillar is substantially the same. 8. The magnetic device of claim 1 , wherein a permeability of the T-shaped magnetic core is μ C , and wherein μ C ≧48 and the core loss P CL (mW/cm 3 ) of the T-shaped magnetic core further satisfies: 0.64 ×f 1.15 ×B m 2.20 ≦P CL ≦4.79 ×f 1.41 ×B m 1.08 . 9. The magnetic device of claim 8 , wherein the annealed soft magnetic metal material is selected from the group consisting of Fe—Si alloy powder that has been pressed into a T-shaped structure and annealed to have the permeability between 48 and 108, Fe—Si—Al alloy powder that has been pressed into the T-shaped structure and annealed to have the permeability between 48 and 150, Fe—Ni alloy powder that has been pressed into the T-shaped structure and annealed to have the permeability between 48 and 192, Fe—Ni—Mo alloy powder that has been pressed into the T-shaped structure and annealed to have the permeability between 48 and 240, and a combination of two or more thereof. 10. The magnetic device of claim 8 , wherein the annealed soft magnetic metal material is selected from the group consisting of Fe—Si—Al alloy powder that has been pressed into the T-shaped structure and annealed to have the permeability between 48 and 150, Fe—Ni alloy powder that has been pressed into the T-shaped structure and annealed to have the permeability between 48 and 192, Fe—Ni—Mo alloy powder that has been pressed into the T-shaped structure and annealed to have the permeability between 48 and 240, and a combination of two or more thereof, and the core loss P cL (mW/cm 3 ) of the T-shaped magnetic core further satisfies: 0.64 ×f 4.31 ×B m 2.20 ≦P CL ≦2.0 ×f 1.41 ×B m 1.08 . 11. The magnetic device of claim 8 , wherein μ C ×Hsat≧2250, where Hsat (Oe) is a strength of the magnetic field at 80% of μ C0 , where μ C0 is the permeability of the T-shaped magnetic core when the strength of the magnetic field is 0. 12. The magnetic device of claim 1 , wherein an equivalent permeability of the magnetic device is between 28.511 and 52.949.