Magnetic resonance imaging apparatus and SAR prediction method

The invention claimed is: 1. A magnetic resonance imaging apparatus comprising: a static magnetic field generation section that applies a static magnetic field to an imaging space; a bed on which an object is disposed in the imaging space; a gradient magnetic field coil that applies a gradient magnetic field to the imaging space; an irradiation coil that irradiates the imaging space with a high frequency magnetic field; a reception coil that receives a nuclear magnetic resonance signal generated by the object in the imaging space; and a control section that controls a timing at which the gradient magnetic field is applied from the gradient magnetic field coil and a timing at which the high frequency magnetic field is applied from the irradiation coil according to a predetermined imaging pulse sequence, wherein the control section includes a specific absorption rate (SAR) prediction unit that predicts a specific absorption rate obtained when the imaging pulse sequence is executed on the object, and wherein the SAR prediction unit, while causing the irradiation coil to irradiate the object with a high frequency magnetic field pulse in a state in which the object is disposed in the imaging space, detects a transmitted voltage and a reflected voltage of the irradiation coil, and then the SAR prediction unit determines a Q (quality) factor of the irradiation coil in the state in which the object is disposed in the imaging space and on the basis of the transmitted voltage and the reflected voltage, obtains a radio frequency (RF) absorption amount of the object on the basis of the Q factor, and predicts the SAR by using the RF absorption amount obtained based on the Q factor, and the control section adjusts the imaging pulse sequence based on the predicted SAR received from the SAR prediction unit. 2. The magnetic resonance imaging apparatus according to claim 1 , wherein the high frequency magnetic field pulse which is caused to be applied by the SAR prediction unit has a predetermined frequency, a standing wave ratio is obtained on the basis of the detected transmitted voltage and reflected voltage of the irradiation coil, and the Q factor is obtained by using the standing wave ratio. 3. The magnetic resonance imaging apparatus according to claim 2 , wherein the SAR prediction unit obtains the Q factor corresponding to a value of the standing wave ratio on the basis of a relationship between a standing wave ratio and a Q factor, obtained in advance. 4. The magnetic resonance imaging apparatus according to claim 2 , wherein a frequency of the high frequency magnetic field pulse is a resonance frequency of water. 5. The magnetic resonance imaging apparatus according to claim 1 , wherein the SAR prediction unit causes the object to be irradiated with a high frequency magnetic field pulse having a predetermined frequency different from the high frequency magnetic field pulse for obtaining the Q factor, detects transmitted power and reflected power of the irradiation coil, and predicts the SAR by using a difference therebetween and the Q factor. 6. The magnetic resonance imaging apparatus according to claim 1 , wherein the SAR prediction unit causes the high frequency magnetic field pulse to be applied for multiple times at different frequencies, detects a transmitted voltage and a reflected voltage of the irradiation coil for each irradiation, obtains impedances on the basis of the transmitted voltage and the reflected voltage, and obtains the Q factor by using a maximum value of the impedances. 7. The magnetic resonance imaging apparatus according to claim 6 , wherein the SAR prediction unit obtains the Q factor by using a frequency at which the impedance becomes the maximum value, and frequencies at which the impedance becomes a half of the maximum value. 8. The magnetic resonance imaging apparatus according to claim 6 , wherein the SAR prediction unit obtains the Q factor corresponding to the maximum value of the impedance on the basis of a relationship between a maximum value of the impedance and a Q factor, obtained in advance. 9. The magnetic resonance imaging apparatus according to claim 1 , wherein the irradiation coil is connected to a signal line through which a high frequency signal for generating the high frequency magnetic field pulse is supplied, and the signal line is provided with a directional coupler which detects a transmitted voltage and a reflected voltage of the irradiation coil. 10. A magnetic resonance imaging apparatus comprising: a static magnetic field generation section that applies a static magnetic field to an imaging space; a bed on which an object is disposed in the imaging space; a gradient magnetic field coil that applies a gradient magnetic field to the imaging space; an irradiation coil that irradiates the imaging space with a high frequency magnetic field; a reception coil that receives a nuclear magnetic resonance signal generated by the object in the imaging space; and a control section that controls a timing at which the gradient magnetic field is applied from the gradient magnetic field coil and a timing at which the high frequency magnetic field is applied from the irradiation coil according to a predetermined imaging pulse sequence, wherein the control section includes a specific absorption rate (SAR) prediction unit that predicts a specific absorption rate obtained when the imaging pulse sequence is executed on the object, and wherein the SAR prediction unit causes the irradiation coil to irradiate the object with a high frequency magnetic field pulse in a state in which the object is disposed in the imaging space, detects a transmitted voltage and a reflected voltage of the irradiation coil, obtains a Q (quality) factor of the irradiation coil on the basis of the transmitted voltage and the reflected voltage, obtains a radio frequency (RF) absorption amount of the object on the basis of the Q factor, and predicts the SAR by using the RF absorption amount, and the control section adjusts the imaging pulse sequence based on the predicted SAR received from the SAR prediction unit, and wherein the specific absorption rate (SAR) prediction unit obtains the RF absorption amount P object according to P object =(P fwd −P rfl )*(1−Q/Q′) where P fwd is transmitted power, P rfl is reflected power, Q is a Q factor value measured with the object in the irradiation coil, and Q′ is a Q factor value measured without the object in the irradiation coil.