Impact rotation tool and impact rotation tool attachment

The invention claimed is: 1. An impact rotation tool comprising: a drive source; an impact force generation unit configured to generate an impact force for converting power from the drive source to pulsed torque; a shaft arranged to transmit the pulsed torque to a bit used to perform a tightening task; a torque measurement unit configured to measure torque applied to the shaft as measured torque; a rotation angle measurement unit configured to measure a rotation angle of the shaft; a tightening torque calculation unit configured to calculate an angular acceleration from the rotation angle and calculate a tightening torque based on the angular acceleration and the measured torque; and a controller configured to control the drive source based on the tightening torque, wherein when T represents the tightening torque, Ts represents the measured torque, I represents a moment of inertia of the shaft, and α represents the angular acceleration, the tightening torque calculation unit is configured to calculate the tightening torque from the equation of T=Ts×A−I×α×B+C, where A, B, and C are correction coefficients. 2. The impact rotation tool according to claim 1 , wherein the tightening torque calculation unit is configured to calculate an approximation curve of the rotation angle measured by the rotation angle measurement unit and to calculate the angular acceleration by differentiating the approximation curve twice. 3. The impact rotation tool according to claim 2 , wherein the tightening torque calculation unit is configured to calculate a quadratic approximation curve of the rotation angle measured by the rotation angle measurement unit and to calculate the angular acceleration by differentiating the quadratic approximation curve twice. 4. The impact rotation tool according to claim 1 , wherein the tightening torque calculation unit is configured to calculate the average value of the measured torque during a predetermined period and to calculate the average value of the angular acceleration during the predetermined period. 5. The impact rotation tool according to claim 1 , wherein the tightening torque calculation unit is configured to determine a tightening period from a first timing to a second timing whenever an impact force is generated, wherein the first timing is when the rotation angle increased by the present impact force becomes the same as a maximum rotation angle obtained during the generation of the preceding impact force, and the second timing is when the rotation angle increased by the present impact force becomes a maximum rotation angle obtained during the generation of the present impact force, and the tightening torque calculation unit is configured to calculate an approximation curve of the rotation angle based on a period including at least part of the tightening period. 6. The impact rotation tool according to claim 1 , wherein the measured torque obtained by the torque measurement unit is a peak value of a predetermined period. 7. An impact rotation tool attachment that is attachable to an impact rotation tool, wherein the impact rotation tool includes an impact force generation unit configured to generate impact force for converting power from a drive source to pulsed torque, a shaft arranged to transmit the pulsed torque to a bit used to perform a tightening task, and a controller configured to control the drive source, the attachment comprising: a torque measurement unit configured to measure torque applied to the shaft as a measured torque; a rotation angle measurement unit configured to measure a rotation angle of the shaft; and a tightening torque calculation unit configured to calculate an angular acceleration from the rotation angle to calculate a tightening torque based on the angular acceleration and the measured torque, wherein when T represents the tightening torque, Ts represents the measured torque, I represents a moment of inertia of the shaft, and α represents the angular acceleration, the tightening torque calculation unit is configured to calculate the tightening torque from the equation of T=Ts×A−I×α×B+C, where A, B, and C are correction coefficients. 8. An impact rotation tool comprising: a drive source; an impact force generation unit configured to generate an impact force for converting power from the drive source to pulsed torque; a shaft arranged to transmit the pulsed torque to a bit used to perform a tightening task; a first measurement unit configured to measure torque applied to the shaft as a measured torque; a second measurement unit configured to measure at least one of acceleration in a circumferential direction of the shaft and an angular velocity of the shaft; a torque computation unit configured to calculate a tightening torque from the measured torque of the first measurement unit and an inertial torque of the shaft and the bit obtained with a measured value of the second measurement unit; and a controller configured to control the drive source based on the tightening torque, wherein when T2 represents the tightening torque, T1 represents the measured torque of the first measurement unit, a1 represents an angular acceleration of the shaft obtained from the measured value of the second measurement unit, and I1 represents a moment of inertia of the bit and a portion of the shaft located at a distal side of where the second measurement unit is coupled, the torque computation unit is configured to calculate the tightening torque from the equation of T2=T1×A−I1×a1×B+C, where A, B, and C are correction coefficients. 9. The impact rotation tool according to claim 8 , wherein the torque computation unit is configured to use an average value of a predetermined period for one or both of the measured torque of the first measurement unit and an angular acceleration of the shaft obtained from the measured value of the second measurement unit. 10. The impact rotation tool according to claim 8 , wherein: the second measurement unit is coupled to a peripheral portion of the shaft and configured to measure acceleration in the circumferential direction of the shaft; the torque computation unit is configured to obtain the angular acceleration by dividing the acceleration in the circumferential direction of the shaft by the distance from a center position of the shaft to a coupling position of the second measurement unit; and the torque computation unit is configured to calculate the tightening torque using (i) the maximum value of the angular acceleration in a rotation stop direction of the drive source, (ii) the angular acceleration at a predetermined time before or after when the angular acceleration is the maximum in the rotation stop direction, or (iii) an average value of the angular acceleration in a predetermined period including when the angular acceleration is the maximum in the rotation stop direction. 11. The impact rotation tool according to claim 8 , wherein: the second measurement unit is coupled to a peripheral portion of the shaft and configured to measure acceleration in a circumferential direction of the shaft and acceleration in a radial direction of the shaft; the torque computation unit is configured to obtain the angular acceleration by dividing the acceleration in the circumferential direction of the shaft by the distance from a center position of the shaft to a coupling position of the second measurement unit; and the torque computation unit is configured to calculate the tightening torque using (i) the angular acceleration at a predetermined time before a stop timing at which the acceleration in the radial direction of the shaft becomes zero or (ii) an average value of the angular acceleration in a