Rotation speed measuring system

The invention claimed is: 1. A rotation speed measuring system that measures a rotation speed of a ball moving in midair, the rotation speed measuring system comprising: a magnetic sensor that is provided in the ball and measures earth magnetism at least in one axis direction; an acceleration sensor that is provided in the ball and measures acceleration at least in one axis direction; an end detecting unit that detects, as an end time point at which midair movement of the ball is considered to end, a time point at which an acceleration variation, obtained as an absolute value of a variation in the acceleration measured by the acceleration sensor in a predetermined small time unit, is switched to a large-variation state from a small-variation state, wherein the small-variation state corresponds to a state in which the acceleration variation is equal to or below a predetermined first threshold value and the large-variation state corresponds to a state in which the acceleration variation is equal to or above a predetermined second threshold value; and a calculating unit that calculates the rotation speed of the ball moving in midair by analyzing a frequency of measurement data on the earth magnetism acquired by the magnetic sensor until the end time point. 2. The rotation speed measuring system according to claim 1 , further comprising a start detecting unit that detects, as a start time point at which the midair movement of the ball is considered to be started, a time point of an end of an initial-variation state in which the acceleration variation is equal to or above a predetermined third threshold value after measurement of the acceleration by the acceleration sensor is started, wherein the calculating unit is configured to calculate the rotation speed of the ball moving in midair by analyzing the frequency of the measurement data on the earth magnetism acquired by the magnetic sensor from the start time point until the end time point. 3. The rotation speed measuring system according to claim 1 , wherein the acceleration sensor is configured to measure acceleration in a plurality of axis directions different from one another, and the end detecting unit is configured to detect the end time point by choosing a portion of measured data having a largest amount of change in the acceleration in the large-variation state from portions of the measurement data on the acceleration in the plurality of axis directions. 4. The rotation speed measuring system according to claim 3 , wherein the acceleration sensor is configured to measure the acceleration in three axis directions orthogonal to one another. 5. The rotation speed measuring system according to claim 4 , wherein the magnetic sensor is configured to measure the earth magnetism in a plurality of axis directions different from one another, and the calculating unit is configured to calculate the rotation speed of the ball by choosing a portion of measurement data having a largest amplitude from portions of the measurement data on the earth magnetism in the plurality of axis directions. 6. The rotation speed measuring system according to claim 5 , wherein the magnetic sensor is configured to measure the earth magnetism in three axis directions orthogonal to one another. 7. The rotation speed measuring system according to claim 3 , wherein the magnetic sensor is configured to measure the earth magnetism in a plurality of axis directions different from one another, and the calculating unit is configured to calculate the rotation speed of the ball by choosing a portion of measurement data having a largest amplitude from portions of the measurement data on the earth magnetism in the plurality of axis directions. 8. The rotation speed measuring system according to claim 7 , wherein the magnetic sensor is configured to measure the earth magnetism in three axis directions orthogonal to one another. 9. The rotation speed measuring system according to claim 1 , wherein the magnetic sensor is configured to measure the earth magnetism in a plurality of axis directions different from one another, and the calculating unit is configured to calculate the rotation speed of the ball by choosing a portion of measurement data having a largest amplitude from portions of the measurement data on the earth magnetism in the plurality of axis directions. 10. The rotation speed measuring system according to claim 9 , wherein the magnetic sensor is configured to measure the earth magnetism in three axis directions orthogonal to one another. 11. The rotation speed measuring system according to claim 1 , wherein the ball is provided with a magnetic sensor memory in which the measurement data on the earth magnetism is to be stored, with a measurement time point of each measured value included in the measurement data being distinguishable. 12. The rotation speed measuring system according to claim 1 , wherein the ball is provided with an acceleration sensor memory in which the measurement data on the acceleration is to be stored, with a measurement time point of each measured value included in the measurement data being distinguishable. 13. The rotation speed measuring system according to claim 1 , wherein the end detecting unit is provided in the ball. 14. The rotation speed measuring system according to claim 1 , wherein the magnetic sensor is constituted by a magneto-impedance sensor. 15. The rotation speed measuring system according to claim 1 , wherein the acceleration includes deceleration. 16. A rotation speed measuring system that measures a rotation speed of a ball moving in midair, the rotation speed measuring system comprising: a magnetic sensor that is provided in the ball and measures earth magnetism at least in one axis direction; an acceleration sensor that is provided in the ball and measures acceleration at least in one axis direction; an end detector that detects, as an end time point at which midair movement of the ball is considered to end, a time point at which an acceleration variation, obtained as an absolute value of a variation in the acceleration measured by the acceleration sensor in a predetermined small time unit, is switched to a large-variation state after a small-variation state, wherein the small-variation state corresponds to a state in which the acceleration variation is equal to or below a predetermined first threshold value and the large-variation state corresponds to a state in which the acceleration variation is equal to or above a predetermined second threshold value; and a calculator that calculates the rotation speed of the ball moving in midair by analyzing a frequency of measurement data on the earth magnetism acquired by the magnetic sensor until the end time point.