Magnetic resonance imaging apparatus and RF pulse for navigator and imaging sequence applying method

What is claimed is: 1. A magnetic resonance imaging apparatus comprising: a scan section having an RF coil unit configured to execute a navigator sequence which transmits an RF pulse to a subject to obtain each magnetic resonance signal as navigator data and configured to execute an imaging sequence for imaging an abdominal region and to correct an excitation section according to a detected position of a diaphragm using the navigator data; wherein upon execution of the navigator sequence, the RF coil unit is configured to simultaneously excite a first region inside a navigator area, a second region inside the navigator area, and a third region located outside of the navigator area in a plane orthogonal to the navigator area at the same time, wherein the first region is a lung, the second region is a liver, and the third region is a subcutaneous fat, wherein the first and second regions include at least a body-moved region positioned therebetween, the body-moved region including a diaphragm; and a navigator data processor configured to generate a position profile indicative of the relationship between positions of the diaphragm and time based on a phase of the navigator data. 2. The magnetic resonance imaging apparatus according to claim 1 , wherein the RF coil unit is configured to transmit the RF pulse such that an intensity of a navigator data signal obtained from the third region falls between the intensities of the navigator data signals obtained from the first and second regions. 3. The magnetic resonance imaging apparatus according to claim 1 , wherein the RF coil unit is configured to execute the navigator sequence such that the phase of navigator data obtained from the subcutaneous fat differs from the phase of navigator data obtained from the liver. 4. The magnetic resonance imaging apparatus according to claim 3 , wherein the RF coil unit is configured to execute the navigator sequence such that the intensity of a navigator data signal obtained from the subcutaneous fat is lower than the intensity of a navigator data signal obtained from the liver. 5. The magnetic resonance imaging apparatus according to claim 1 , wherein the RF coil unit is configured to execute the navigator sequence such that, upon excitation of the navigator sequence, a gradient magnetic field assumes a spiral trajectory on a k space. 6. The magnetic resonance imaging apparatus according to claim 1 , wherein the RF coil unit is configured to transmit RF pulses for exciting the first and second regions and the third region in cylindrical form respectively. 7. The magnetic resonance imaging apparatus according to claim 5 , wherein a number of turns at the time that the gradient magnetic field assumes a spiral trajectory on a k space, is determined based on a distance interval between the navigator area and the third region. 8. The magnetic resonance imaging apparatus according to claim 5 , wherein the gradient magnetic field is generated so as to assume a spiral trajectory outside as viewed from the center of the k space. 9. The magnetic resonance imaging apparatus according to claim 5 , wherein the gradient magnetic field is generated so as to assume a spiral trajectory in the center of the k space as viewed from outside the k space. 10. An RF pulse applying method comprising: executing, by a processor, a navigator sequence for transmitting an RF pulse to a subject and thereby obtaining each magnetic resonance signal as navigator data; generating a position profile indicative of the relationship between positions of the diaphragm and time based on a phase of the navigator data; and executing an imaging sequence for imaging an abdominal region and to correct and excitation section according to a detected position of a diaphragm using the navigator data; wherein executing the navigator sequence comprises: simultaneously exciting a first region inside a navigator area, a second region inside the navigator area, and a third region located outside of the navigator area in a plane orthogonal to the navigator area at the same time, wherein intensities of different navigator data signals are obtained from the first and second regions, and wherein one of the first and second regions is a body-moved region, wherein the first region is a lung, the second region is a liver, the third region is a subcutaneous fat, and the body-moved region is a diaphragm, and wherein the simultaneously exciting a first region comprises transmitting the RF pulse to the subcutaneous fat set as the third region. 11. The RF pulse applying method according to claim 10 , wherein simultaneously exciting a first region comprises transmitting the RF pulse such that an intensity of a navigator data signal obtained from the third region falls between the intensities of the navigator data signals obtained from the first and second regions. 12. The RF pulse applying method according to claim 10 , wherein simultaneously exciting a first region comprises executing the navigator sequence such that a phase of navigator data obtained from the subcutaneous fat differs from a phase of navigator data obtained from the liver. 13. The RF pulse applying method according to claim 12 , wherein simultaneously exciting a first region comprises executing the navigator sequence such that an intensity of a navigator data signal obtained from the subcutaneous fat is lower than an intensity of a navigator data signal obtained from the liver. 14. The RF pulse applying method according to claim 10 , wherein simultaneously exciting a first region comprises executing the navigator sequence such that, upon excitation of the navigator sequence, a gradient magnetic field assumes a spiral trajectory in a k space. 15. The RF pulse applying method according to claim 10 , wherein simultaneously exciting a first region comprises transmitting RF pulses for exciting the first and second regions and the third region in cylindrical form respectively. 16. The RF pulse applying method according to claim 14 , further comprising determining a number of turns at a time that the gradient magnetic assumes the spiral trajectory on the k space, based on a distance interval between the navigator area and the third region.