Magnetic resonance imaging apparatus, method for controlling the same, and control program of magnetic resonance imaging apparatus

What is claimed is: 1. A magnetic resonance imaging apparatus comprising: a static magnetic field generating device configured to apply a static magnetic field to an imaging region; an imaging unit including an RF signal irradiation device configured to irradiate a subject arranged in the imaging region with a high-frequency magnetic field pulse, and a gradient magnetic field generating device configured to generate a gradient magnetic field pulse, the imaging unit acquiring a nuclear magnetic resonance signal generated from the subject in response to the high-frequency magnetic field pulse and the gradient magnetic field pulse; a processing device coupled to the imaging unit, the processing device controlling the imaging unit to repeatedly execute the application of the high-frequency magnetic field pulse and the gradient magnetic field pulse and the acquisition of the nuclear magnetic resonance signal at predetermined timings in accordance with a predetermined imaging pulse sequence and controlling the imaging unit to acquire a necessary number of nuclear magnetic resonance signals for image reconstruction; and a camera configured to continuously and optically image the subject arranged in the imaging region during an operation of the imaging unit, wherein the processing device takes in images captured by the camera at a predetermined frame rate, the imaging pulse sequence is divided into small sequences at a time width corresponding to the frame rate, and the processing device controls the imaging unit to sequentially execute the small sequences at a time interval corresponding to the frame rate by repeating an operation of: before controlling the imaging unit to execute one small sequence, detecting a displacement of the subject with respect to a predetermined reference position or a motion speed of the subject based on an image of the latest frame taken in at the frame rate, and controlling the imaging unit to execute the small sequence when a detection result is within a predetermined allowable range and waiting until an image of a next frame is taken in according to the frame rate without causing the imaging unit to execute the small sequence when the detection result exceeds the allowable range. 2. The magnetic resonance imaging apparatus according to claim 1 , wherein the processing device detects at least the displacement based on the image of the latest frame, determines whether the detected displacement reaches a predetermined displacement caused by a predetermined cyclic motion of the subject, and control the imaging unit to execute the small sequence when the detection result is within the predetermined allowable range and the displacement of the subject reaches the predetermined displacement caused by the predetermined cyclic motion. 3. The magnetic resonance imaging apparatus according to claim 1 , wherein the processing device detects a cyclic displacement of the subject based on images of a plurality of frames, obtains a time width in which a nuclear magnetic resonance signal can be acquired based on a cycle of the detected displacement, and generates an intermediate sequence by collecting a plurality of small sequences so as to fall within the time width, and the processing device then takes in the image of the latest frame to detect a displacement, determines whether the cyclic displacement of the subject reaches a predetermined displacement, and controls the imaging unit to execute the intermediate sequence when the cyclic displacement reaches the predetermined displacement. 4. The magnetic resonance imaging apparatus according to claim 1 , wherein the processing device receives the frame rate via an operating device. 5. A magnetic resonance imaging apparatus comprising: a static magnetic field generating device configured to apply a static magnetic field to an imaging region; an imaging unit including an RF signal irradiation device configured to irradiate a subject arranged in the imaging region with a high-frequency magnetic field pulse, and a gradient magnetic field generating device configured to generate a gradient magnetic field pulse, the imaging unit acquiring a nuclear magnetic resonance signal generated from the subject in response to the high-frequency magnetic field pulse and the gradient magnetic field pulse; a processing device coupled to the imaging unit, the processing device controlling the imaging unit to repeatedly execute the application of the high-frequency magnetic field pulse and the gradient magnetic field pulse and the acquisition of the nuclear magnetic resonance signal at predetermined timings in accordance with a predetermined imaging pulse sequence and controlling the imaging unit to acquire a necessary number of nuclear magnetic resonance signals for image reconstruction; and a camera configured to continuously and optically image the subject arranged in the imaging region during an operation of the imaging unit, wherein the processing device takes in images captured by the camera at a predetermined frame rate, the imaging pulse sequence is divided into small sequences at a time width corresponding to the frame rate, and the processing device controls the imaging unit to sequentially execute the small sequences by repeating an operation of: before controlling the imaging unit to execute one small sequence, detecting a displacement of the subject based on an image of the latest frame taken in at the frame rate, determining whether the detected displacement reaches a predetermined displacement caused by a predetermined cyclic motion of the subject, and controlling the imaging unit to execute the small sequence when the detected displacement reaches the predetermined displacement and waiting until an image of a next frame is taken in according to the frame rate without executing the small sequence when the detected displacement does not reach the predetermined displacement. 6. The magnetic resonance imaging apparatus according to claim 5 , wherein the processing device receives the frame rate via an operating device. 7. The magnetic resonance imaging apparatus according to claim 5 , wherein the processing device detects at least the displacement based on the image of the latest frame, determines whether the detected displacement reaches a predetermined displacement caused by a predetermined cyclic motion of the subject, and causes the imaging unit to execute the small sequence when the detection result is within the predetermined allowable range and the displacement of the subject reaches the predetermined displacement caused by the predetermined cyclic motion. 8. The magnetic resonance imaging apparatus according to claim 5 , wherein the processing device detects a cyclic displacement of the subject based on images of a plurality of frames, obtains a time width in which a nuclear magnetic resonance signal can be acquired based on a cycle of the detected displacement, and generates an intermediate sequence by collecting a plurality of small sequences so as to fall within the time width, and the processing device then takes in the image of the latest frame to detect a displacement, determines whether the cyclic displacement of the subject reaches a predetermined displacement, and causes the imaging unit to execute the intermediate sequence when the cyclic displacement reaches the predetermined displacement. 9. A magnetic resonance imaging apparatus comprising: a static magnetic field generating device configured to apply a static magnetic field to an imaging region; an imaging unit including an RF signal irradiation device configured to irradiate a subject arranged in the imaging region with a high-frequency magnetic field pulse, and a gradient magnetic field generating device conf