Magnetic resonance imaging method and magnetic resonance imaging apparatus

The invention claimed is: 1. A magnetic resonance imaging method comprising: selecting a first set of RF pulses; applying the first set of RF pulses to a portion of an object; generating a first image in response to signal data obtained from the first set of RF pulses; selecting a second set of RF pulses, wherein at least one pulse of the second set of RF pulses has a different gradient than one of the pulses of the first set of RF pulses; applying the second set of RF pulses to the same portion of the object as the first set of RF pulses; generating a second image in response to signal data obtained from the second set of RF pulses; comparing the first image and the second image to determine whether there is a distorted region present in the first image or the second image, each of the first image and the second image having a total field of view that is a distance of the image along an axis; assigning an affected field of view to a width of the distorted region along an axis of one or both of the first image and the second image; determining an acceleration factor by dividing a total field of view of one or both of the first image and the second image by the affected field of view; acquiring sampled image data according to the acceleration factor of one or both of the first image and the second image; generating a third image from the acquired sampled image data and applying a mask to the third image in the affected field of view; and displaying the third image. 2. The magnetic resonance imaging method of claim 1 , wherein each pulse of the second set of RF pulses has a different gradient than each pulse of the first set of RF pulses. 3. The magnetic resonance imaging method of claim 1 , wherein each pulse of the first set of RF pulses has a different gradient than each pulse of the second set of RF pulses. 4. The magnetic resonance imaging method of claim 1 , wherein each set of pulses comprises a first excitation pulse and a second refocus pulse. 5. The magnetic resonance imaging method of claim 1 , wherein each set of pulses comprises a first excitation pulse and two or more second refocus pulses. 6. The magnetic resonance imaging method of claim 1 , further comprising selecting and applying one or more additional sets of pulses after the second set of RF pulses is applied. 7. The magnetic resonance imaging method of claim 1 , wherein a width of the mask is set to be the same as the affected field of view. 8. The magnetic resonance imaging method of claim 1 , wherein the mask reduces or removes aliases from the third image. 9. The magnetic resonance imaging method of claim 1 , further comprising a step of correcting a readout distortion by applying view angle tilting. 10. A magnetic resonance imaging method comprising: selecting a first RF pulse; applying the first RF pulse to a portion of an object; selecting a second RF pulse, the second RF pulse being at a different gradient than the first RF pulse, at a different bandwidth than the first RF pulse or at a different gradient and a different bandwidth than the first RF pulse; applying the second RF pulse to the same portion of the object as the first RF pulse; generating an image in response to signal data obtained from the second RF pulse; determining whether there is a distorted region present in the data of the image, with the image having a total field of view that is the distance of the image along an axis; assigning an affected field of view to a width of the distorted region along the axis of the image; determining an acceleration factor by dividing the total field of view of the image by the affected field of view; acquiring sampled image data according to the acceleration factor of the image; generating a second image from the acquired sampled image data and applying a mask to the second image in the affected field of view; and displaying the second image. 11. The magnetic resonance imaging method of claim 10 , wherein a width of the mask is set to be the same as the affected field of view. 12. The magnetic resonance imaging method of claim 10 , wherein the mask reduces or removes aliases from the second image. 13. The magnetic resonance imaging method of claim 10 , further comprising a step of correcting a readout distortion by applying view angle tilting. 14. The magnetic resonance imaging method of claim 10 , wherein the second RF pulse is an excitation pulse. 15. The magnetic resonance imaging method of claim 10 , wherein the second RF pulse is a refocus pulse. 16. A magnetic resonance imaging apparatus comprising: a magnetic resonance imaging sequence controller that is configured to select a first set of RF pulses, select a second set of RF pulses where at least one pulse of the second set of RF pulses has a different gradient than one of the pulses of the first set of RF pulses, apply the first set of RF pulses to a portion of an object, apply the second set of RF pulses to the same portion of the object as the first set of RF pulses, a magnetic resonance imaging processor configured to generate a first image from obtained signal data of the first set of RF pulses and generate a second image from obtained signal data of the second set of RF pulses, compare the first image and the second image to determine whether there is a distorted region present in the first image or the second image, assign an affected field of view to a width of the distorted region along an axis of one or both of the first image and the second image, determine an acceleration factor by dividing a total field of view of one or both of the first image and the second image by the affected field of view and acquire sampled k-space data according to the acceleration factor of one or both of the first image and second image. 17. The magnetic resonance imaging apparatus of claim 16 , wherein the magnetic resonance imaging processor generates a third image from the acquired sampled image data and the magnetic resonance imaging sequence controller applies a mask to the third image in the affected field of view.