Internal gear machining method and internal gear machining device

The invention claimed is: 1. An internal gear machining method in which an internal gear grinding machine performs grinding of a tooth surface of an internal gear using a barrel-shaped threaded grinding wheel having multiple teeth by synchronously rotating the internal gear and the barrel-shaped threaded grinding wheel in mesh with each other with a crossed-axes angle formed between the internal gear and the barrel-shaped threaded grinding wheel, the method comprising: measuring, by a gear accuracy measuring device installed in the internal gear grinding machine, pressure angle errors in the tooth surface of the internal gear, a tooth trace error in the tooth surface of the internal gear, and a tooth thickness error in the tooth surface of the internal gear; reducing the measured pressure angle errors by correcting a radial position, a grinding wheel lateral position, a grinding wheel turning angle, and a helical motion; reducing the measured tooth trace error by correcting the helical motion; and reducing the measured tooth thickness error by correcting the radial position, the grinding wheel turn angle, and the helical motion. 2. The internal gear machining method according to claim 1 , wherein first, a correction amount for the helical motion is set that causes the tooth trace error to be reduced, next, a correction amount for a grinding wheel lateral position is set that causes the pressure angle errors being asymmetric to be reduced, then, a correction amount for the radial position error and a correction amount for the grinding wheel turning angle are set that cause the pressure angle errors being symmetric and the tooth thickness error to be reduced, and the radial position, the grinding wheel lateral position, the grinding wheel turning angle, and the helical motion are corrected based on the correction amounts. 3. The internal gear machining method according to claim 2 , wherein analyses are made in advance for an influence of a radial position error, a grinding wheel lateral position error, a grinding wheel turning angle error, and a helical motion error on the pressure angle errors, an influence of the helical motion error on the tooth trace error, and an influence of the radial position error, the grinding wheel turning angle error, and the helical motion error on the tooth thickness error, based on results of the analyses, the correction amounts for the radial position, the grinding wheel lateral position, the helical motion, and the grinding wheel turning angle are set that cause the pressure angle errors, the tooth trace error, and the tooth thickness error to be reduced, and the radial position, the grinding wheel lateral position, the helical motion, and the grinding wheel turning angle are corrected based on the correction amounts. 4. The internal gear machining method according to claim 2 , wherein the internal gear is a spur gear, and the correction amount for the helical motion is set to zero. 5. The internal gear machining method according to claim 1 , wherein analyses are made in advance for an influence of a radial position error, a grinding wheel lateral position error, a grinding wheel turning angle error, and a helical motion error on the pressure angle errors, an influence of the helical motion error on the tooth trace error, and an influence of the radial position error, the grinding wheel turning angle error, and the helical motion error on the tooth thickness error, based on results of the analyses, the correction amounts for the radial position, the grinding wheel lateral position, the helical motion, and the grinding wheel turning angle are set that cause the pressure angle errors, the tooth trace error, and the tooth thickness error to be reduced, and the radial position, the grinding wheel lateral position, the helical motion, and the grinding wheel turning angle are corrected based on the correction amounts. 6. The internal gear machining method according to claim 5 , wherein the internal gear is a spur gear, and the correction amount for the helical motion is set to zero. 7. The internal gear machining method according to claim 1 , wherein the internal gear is a spur gear, and the correction amount for the helical motion is set to zero. 8. An internal gear machining apparatus in which an internal gear grinding machine performs grinding of a tooth surface of an internal gear using a barrel-shaped threaded grinding wheel having multiple teeth by synchronously rotating the internal gear and the barrel-shaped threaded grinding wheel in mesh with each other with a crossed-axes angle formed between the internal gear and the barrel-shaped threaded grinding wheel, the internal gear machining apparatus comprising: a gear accuracy measurer installed in the internal gear grinding machine, and that measures pressure angle errors in the tooth surface of the internal gear, a tooth trace error in the tooth surface of the internal gear, and a tooth thickness error in the tooth surface of the internal gear; and a tooth profile error corrector that includes a processor and stores instructions that causes the processor to: reduce the measured pressure angle errors by correcting a radial position, a grinding wheel lateral position, a grinding wheel turning angle, and a helical motion; reduce the measured tooth trace error by correcting the helical motion; and reduce the measured tooth thickness error by correcting the radial position, the grinding wheel turning angle, and the helical motion. 9. The internal gear machining apparatus according to claim 8 , wherein the tooth profile error corrector first, sets a correction amount for the helical motion that causes the tooth trace error to be reduced; next, sets a correction amount for a grinding wheel lateral position that causes the pressure angle errors being asymmetric to be reduced; then, sets a correction amount for the radial position error and a correction amount for the grinding wheel turning angle that cause the pressure angle errors being symmetric and the tooth thickness error to be reduced; and corrects the radial position, the grinding wheel lateral position, the grinding wheel turning angle, and the helical motion on the basis of the correction amounts. 10. The internal gear machining apparatus according to claim 9 , wherein the tooth profile error corrector sets the correction amounts for the radial position, the grinding wheel lateral position, the helical motion, and the grinding wheel turning angle that cause the pressure angle errors, the tooth trace error, and the tooth thickness error to be reduced, on the basis of analyses made in advance for an influence of a radial position error, a grinding wheel lateral position error, a grinding wheel turning angle error, and a helical motion error on the pressure angle errors, an influence of the helical motion error on the tooth trace error, and an influence of the radial position error, the grinding wheel turning angle error, and the helical motion error on the tooth thickness error, and the tooth profile error corrector corrects the radial position, the grinding wheel lateral position, the helical motion, and the grinding wheel turning angle on the basis of the correction amounts. 11. The internal gear machining apparatus according to claim 9 , wherein the internal gear is a spur gear, and the tooth profile error correction means sets the correction amount for the helical motion to zero. 12. The internal gear machining apparatus according to claim 8 wherein the tooth profile error corrector sets the correction amounts for the radial position, the grinding wheel lateral position, the helical motion, and the grind