Magnetic head, magnetic recording method and apparatus for controlling magnetic head with spin torque oscillator in a disk drive

What is claimed is: 1. A microwave assisted magnetic recording head comprising: a recording magnetic pole unit configured to produce a recording field for writing to a perpendicular magnetic recording medium; and a high-frequency magnetic field oscillator configured to produce a high-frequency magnetic field, wherein: the recording magnetic pole unit includes a longitudinal recording magnetic core with a write gap in which a longitudinal magnetic recording field component is produced as a main magnetic recording field component substantially perpendicular to a surface of the magnetic recording medium; the magnetic core is configured such that an oscillation control magnetic field is applied in the write gap substantially perpendicular to the high-frequency magnetic field oscillator and substantially parallel to the surface of the magnetic recording medium; and the high-frequency magnetic field oscillator is disposed in the write gap. 2. The microwave assisted magnetic recording head according to claim 1 , wherein a magnetization reversal region of a perpendicular magnetic recording medium statically recorded by magnetizing the magnetic core with a write current has a shape corresponding to the shape of the write gap. 3. The microwave assisted magnetic recording head according to claim 1 , wherein the magnetic core includes a trailing side recording magnetic pole with a track width of 40 nm to 250 nm, a gap depth of 40 nm to 700 nm, and a write gap length of 20 nm to 200 nm. 4. The microwave assisted magnetic recording head according to claim 1 , wherein the magnetic core has a yoke length of not less than 0.5 μm and not more than 4 μm. 5. The microwave assisted magnetic recording head according to claim 1 , wherein the high-frequency magnetic field oscillator includes: a formed member including two high-frequency magnetic field oscillation layers layered via a coupling layer of a non-magnetic material; an intermediate layer; and a spin injection layer, wherein an electric current is caused to flow from the spin injection layer side toward the formed member side via the intermediate layer. 6. The microwave assisted magnetic recording head according to claim 5 , wherein the coupling layer has a film thickness of not less than 0.1 nm and not more than 0.7 nm, not less than 1.2 nm and not more than 1.6 nm, or not less than 2.7 nm and not more than 3.2 nm. 7. The microwave assisted magnetic recording head according to claim 1 , wherein: the high-frequency magnetic field oscillator includes a high-frequency magnetic field oscillation layer of a magnetic film with a magnetic easy axis in a longitudinal direction, a non-magnetic intermediate layer, and a spin injection layer; the spin injection layer includes a magnetic film configured to have a magnetization orientated effectively in a film surface longitudinal direction, and is layered with the high-frequency magnetic field oscillation layer via the non-magnetic intermediate layer such that the magnetization is antiferromagnetically coupled with magnetization of the high-frequency magnetic field oscillation layer; and the magnetization of the high-frequency magnetic field oscillation layer and the magnetization of the spin injection layer are rotated at high speed while an antiparallel state is maintained when an electric current flows from the high-frequency magnetic field oscillation layer side toward the spin injection layer side. 8. The microwave assisted magnetic recording head according to claim 1 , wherein the high-frequency magnetic field oscillator has a width of 3 nm to 100 nm. 9. A magnetic recording apparatus comprising: a microwave assisted magnetic recording head including a recording magnetic pole including a longitudinal recording magnetic core with a write gap in which a longitudinal magnetic recording field component is produced as a main magnetic recording field component substantially perpendicular to a surface of the magnetic recording medium, the magnetic core is configured such that an oscillation control magnetic field is applied in the write gap substantially perpendicular to the high-frequency magnetic field oscillator and substantially parallel to the surface of the magnetic recording medium, a high-frequency magnetic field oscillator disposed in the write gap, a magnetic reproduction element configured to read information from a perpendicular magnetic recording medium, and a thermal flying height controller (TFC) element configured to adjust a clearance between the high-frequency magnetic field oscillator and the perpendicular magnetic recording medium; a unit configured to control or process a recording operation by the recording magnetic pole and the high-frequency magnetic field oscillator, and a reproduction operation by the magnetic reproduction element; and a TFC control unit configured to control an operation of the TFC element. 10. The magnetic recording apparatus according to claim 9 , wherein: at least at the time of the recording operation, a write current smaller than a lower limit value enabling the perpendicular magnetic recording medium to be recorded is supplied to the magnetic core; and at least during a manufacturing process, the values of the write current, the high-frequency oscillator drive current, and power supplied to the TFC element are adjusted to be values such that the recording/reproduction characteristics in a predetermined region of the magnetic recording apparatus are optimized. 11. The magnetic recording apparatus according to claim 9 , comprising a temperature sensor and/or an atmospheric pressure sensor in the apparatus, wherein, when the environment of the magnetic recording apparatus is changed, the values of a write current supplied to the magnetic core, a drive current for the high-frequency oscillator, and an input power to the TFC element are readjusted. 12. The magnetic recording apparatus according to claim 9 , wherein, when recording or reproduction is started in response to a recording or reproduction instruction from a pause state in which no recording or reproduction instruction is received from a higher-level system for a predetermined time: predetermined energization of the magnetic core is started in advance under a predetermined condition; the high-frequency magnetic field oscillator is operated in accordance with the input of a write gate indicating information recording after a predetermined delay time; and a recording operation is started by operating the magnetic core. 13. The magnetic recording apparatus according to claim 9 , wherein, when a characteristics degradation due to a clearance change by a rapid atmospheric pressure change or contamination is confirmed, a write current supplied to the magnetic core, a drive current for the high-frequency magnetic field oscillator, and input power to the TFC element are changed in accordance with the amount of clearance change predicted on the basis of an output change and the like, until the clearance returns to an initial value. 14. The magnetic recording apparatus according to claim 9 , wherein, when a characteristics degradation due to a rapid temperature change is confirmed, a write current supplied to the magnetic core and a drive current for the high-frequency magnetic field oscillator are adjusted in such a manner as to compensate for a characteristics change predicted on the basis of the temperature change, and the write current supplied to the magnetic core and the drive current for the high-frequency magnetic field oscillator are shifted to a setting value corresponding to an ambient temperature by a predetermined method until the ch