Optical filter

What is claimed is: 1. An optical filter which is used to control a signal for a right eye and a signal for a left eye to have different polarized states from each other, wherein the signals for the right eye and for the left eye are emitted from a stereoscopic image display device comprising a display part comprising signal generating regions for a right eye and a left eye configured to generate the signals for the right eye and left eye; and a first light transmission control region adjacent to the signal generating regions for the right eye and the left eye, and which comprises a liquid crystal layer having first and second regions adjacent to each other which are capable of dividing incident light into at least two kinds of lights having different polarized states and emitting the divided lights; and a second light transmission control region in the boundary between the first and second regions, wherein the second light transmission control region is formed so that the maximum value of an angle “θ U ” satisfying Expression 2 and the maximum value of an angle “θ L ” satisfying Expression 3 are three degrees or more, wherein the stereoscopic image display device to which the optical filter is applied has a relative brightness of 60% or more when observed from front, wherein the relative brightness refer to a ratio of brightness I T of the stereoscopic image display device having the first light transmission control region and the second light transmission control region formed with respect to brightness I O of a stereoscopic image display device having neither the first light transmission control region nor the second light transmission control region: tan θ U =( H 1 +2 y )/2 T   [Expression 2] tan θ L =( H 1 +2 H 2 −2 y )/2 T   [Expression 3] where H 1 is the width of the first light transmission control region of the stereoscopic image display device, H 2 is the width of the second light transmission control region of the optical filter, T is the distance from the display part to the optical filter in the device to which the optical filter is applied, and y is the distance from a point at which an imaginary normal line bisecting the first light transmission control region meets the second light transmission control region, to an end point of the second light transmission control region, in a lateral view of the stereoscopic image display device, wherein the optical filter further comprises a base layer, the liquid crystal layer is formed on the base layer, at least a part of the liquid crystal layer is contacted with the base layer, and the second light transmission control region is between the base layer and the liquid crystal layer, or on the liquid crystal layer's surface, opposite to the surface on which the base layer is formed, and wherein H 2 is in a range of more than 0 to 1000 μm and H 2 is same as or smaller than H 1 . 2. The optical filter according to claim 1 , wherein the liquid crystal layer comprises a multifunctional polymerizable liquid crystal compound and a monofunctional polymerizable liquid crystal compound. 3. The optical filter according to claim 1 , wherein a difference between an in-plane refractive index of a slow axis direction of the liquid crystal layer and an in-plane refractive index of a fast axis direction of the liquid crystal layer is in the range from 0.05 to 0.2 and the liquid crystal layer has a thickness in the range from 0.5 to 2.0 μm. 4. The optical filter according to claim 1 , wherein the light transmission control region has a light transmission rate in the range from 0% to 20%. 5. The optical filter according to claim 1 , wherein the first and second regions are phase retardation regions having optical axes formed in different directions to each other, and the light transmission control region is formed parallel to a line bisecting an angle formed by the optical axes in the first and second regions, or formed on the line bisecting the angle. 6. The optical filter according to claim 1 , wherein the light transmission control region comprises a light blocking or absorbing ink. 7. The optical filter according to claim 1 , further comprising: an alignment layer between the base layer and the liquid crystal layer. 8. The optical filter according to claim 7 , wherein the light transmission control region is between the alignment layer and the liquid crystal layer. 9. The optical filter according to claim 7 , wherein the light transmission control region is between the alignment layer and the base layer. 10. A stereoscopic image display device, comprising: a display part comprising signal generating regions for right and left eyes capable of generating signals for right and left eyes, and a first light transmission control region adjacent to the signal generating regions for right and left eyes; and the optical filter of claim 1 , which is positioned such that one of the first and second regions is at a location to which the signal for the right eye is incident and the other of the first and second regions is at a location to which the signal for the left eye is incident. 11. A method of manufacturing an optical filter which is used to control a signal for a right eye and a signal for a left eye to have different polarized states from each other, wherein the signals for the right eye and for the left eye are emitted from a stereoscopic image display device comprising a display part comprising signal generating regions for a right eye and a left eye configured to generate the signals for the right eye and left eye; and a first light transmission control region adjacent to the signal generating regions for the right eye and the left eye and which comprises, comprising: forming a second light transmission control region on the boundary between first and second regions in a liquid crystal layer comprising the first and second regions which have different phase retardation characteristics and which are adjacent to each other, wherein the second light transmission control region is formed so that the maximum value of an angle “θ U ” satisfying Expression 2 and the maximum value of an angle “θ L ” satisfying Expression 3 are three degrees or more, wherein the stereoscopic image display device to which the optical filter is applied has a relative brightness of 60% or more when observed from front, and wherein the relative brightness refer to a ratio of brightness I T of the stereoscopic image display device having the first light transmission control region and the second light transmission control region formed with respect to brightness I O of a stereoscopic image display device having neither the first light transmission control region nor the second light transmission control region: tan θ U =( H 1 +2 y )/2 T   [Expression 2] tan θ L =( H 1 +2 H 2 −2 y )/2 T   [Expression 3] where H 1 is the width of the first light transmission control region of the stereoscopic image display device, H 2 is the width of the second light transmission control region, T is the distance from the display part to the optical filter in the device to which the optical filter is applied, and y is the distance from a point at which an imaginary normal line bisecting the first light transmission control region meets the second light transmission control region, to an end point of the second light transmission control region, in a lateral view of the stereoscopic image display device, wherein the optical filter further comprises a base layer, the liquid crystal layer is formed on the base layer, at least a part of the liquid crystal layer is contacted with the base layer, and the second light transmission control region is between the base