Glass manufacturing method and apparatus

What is claimed is: 1. A glass manufacturing method comprising: a) determining a plurality of stress values in a glass sheet in a plurality of locations of the glass sheet respectively; b) determining a plurality of light leakage degrees in the plurality of locations respectively for a polarization-based display provided with the glass sheet when the polarization-based display is in a state to block light transmissions; c) calculating a plurality of modified stress values based on a product of the plurality of determined stress values and corresponding assigned weights, the weight for each location varying depending on the determined light leakage degree in each location, wherein the modified stress value at each location varies depending on the corresponding determined light leakage degree of the plurality of light leakage degrees at the corresponding location through the dependence of the weight on the corresponding light leakage degree of the plurality of light leakage degrees; and d) manufacturing at least one additional glass sheet in a glass sheet manufacturing process while adjusting at least one process condition of the glass sheet manufacturing process based on the plurality of modified stress values, wherein the glass sheet manufacturing process comprises a drawing process in which a glass ribbon is drawn and then, cut into the at least one additional glass sheet, and the at least one process condition comprises a transverse temperature profile along a width of the glass ribbon, the width extending transverse to a drawing direction in the drawing process, and a longitudinal direction of the glass sheet is a drawing direction in the drawing process. 2. The method of claim 1 , wherein the plurality of locations comprise a plurality of arrays of locations, and each array of locations arranged in the longitudinal direction of the glass sheet. 3. The method of claim 2 , wherein step a) further comprises calculating an average of the stress values in each array of locations; and wherein step c) calculates the plurality of modified stress values using the average for each array of locations as the determined stress values at each array of locations. 4. The method of claim 1 , wherein each of the plurality of stress values comprises a value of a stress component in the longitudinal direction of the glass sheet. 5. The method of claim 1 , wherein the plurality of locations comprise a plurality of arrays of locations, each array of locations arranged in the longitudinal direction of the glass sheet, wherein step c) comprises: modifying the determined stress values in each array of locations into before-averaging modified stress values; calculating an average of the before-averaging modified stress values in each array of locations; and wherein step d) adjusts the at least one process condition using the average for each array of locations as the modified stress values at each array of locations. 6. The method of claim 1 , wherein step b) further comprises calculating an average of the light leakage degrees in each location, the average of the light leakage degrees at a location is based on the corresponding location and at least one adjacent location adjacent to the corresponding location; and wherein step c) performs the modification using the average for each location as the determined light leakage degree in each location. 7. The method of claim 1 , wherein step a) comprises: b1) obtaining birefringence data in the plurality of locations of the glass sheet, and b2) determining the plurality of stress values from the birefringence data. 8. The method of claim 7 , wherein the birefringence data comprise retardation data and azimuthal angle data in the plurality of locations of the glass sheet. 9. The method of claim 1 , wherein step b) comprises: b1) obtaining birefringence data in the plurality of locations of the glass sheet, and b2) determining the plurality of light leakage degrees from the birefringence data. 10. The method of claim 1 , wherein the polarization-based display is a twisted nematic display. 11. The method of claim 1 , wherein the calculating a plurality of modified stress values comprises multiplying the stress value in each location by the weight for each location. 12. The method of claim 1 , wherein, when any two locations of the plurality of locations in which the light leakage degrees are different such that the light leakage degree in one location of the any two locations is greater than the light leakage degree in the other location of the any two locations are compared, the weight for the one location is greater than or equal to the weight for the other location. 13. The method of claim 12 , wherein, when the light leakage degree in the one location is greater than or equal to a predetermined threshold and the light leakage degree in the other location is lower than the predetermined threshold, the weight in the one location is greater than the weight for the other location. 14. The method of claim 13 , wherein the weight in the one location is proportional to the light leakage degree in the one location and the weight for the other location is 0. 15. The method of claim 1 , wherein step d) adjusts the transverse temperature profile by independently adjusting operation of a plurality of temperature adjusting elements positioned along the width of the glass ribbon. 16. The method of claim 15 , wherein step d) independently adjusts powers provided to the plurality of temperature adjusting elements respectively. 17. The method of claim 1 , wherein step d) controls the plurality of modified stress values in the at least one additional glass sheet by adjusting the at least one process condition for the at least one additional glass sheet. 18. The method of claim 1 , further comprising the step of: e) repeating steps a) to d). 19. A glass manufacturing apparatus comprising: a manufacturing apparatus configured to form a glass ribbon and then, separate a glass sheet from the glass ribbon, in a glass sheet manufacturing process; an adjusting apparatus configured to adjust at least one process condition of the glass manufacturing process; and a control device configured to: determine a plurality of stress values in the glass sheet in a plurality of locations of the glass sheet respectively; determine a plurality of light leakage degrees in the plurality of locations respectively for a polarization-based display provided with the glass sheet, when the polarization-based display is in a state to block light transmission; calculate a plurality of modified stress values based on a product of the plurality of determined stress values and corresponding assigned weights, the weight for each location varying depending on the determined light leakage degree in each location, wherein the modified stress value at each location varies depending on the corresponding determined light leakage degree of the plurality of light leakage degrees at the corresponding location through the dependence of the weight on the corresponding light leakage degree of the plurality of light leakage degrees; and control the adjusting device to adjust the at least one process condition based on the plurality of modified stress values. 20. The adjusting apparatus of claim 19 , wherein the adjusting apparatus comprises a plurality of temperature adjusting elements positioned at respective lateral locations along at least one temperature adjusting axis perpendicular to a drawing direction. 21.