Optical film

What is claimed is: 1. An optical film, comprising: a laminate comprising a positive biaxial phase retardation layer, and an optical anisotropic layer selected from the group consisting of a positive uniaxial phase retardation layer, a negative uniaxial phase retardation layer, a positive biaxial phase retardation layer, and a negative biaxial phase retardation layer; wherein the positive biaxial phase retardation layer and the optical anisotropic layer are in direct contact, separated by an adhesive, or separated by a pressure-sensitive adhesive, wherein an optical axis of the positive biaxial phase retardation layer is perpendicular to an optical axis of the optical anisotropic layer, and wherein “perpendicular” includes an error within approximately ±15 degrees and “optical axis” refers to a slow axis; wherein the positive uniaxial phase retardation layer satisfies following Expression 1, the negative uniaxial phase retardation layer satisfies following Expression 2, the positive biaxial phase retardation layer satisfies following Expression 3, and the negative biaxial phase retardation layer satisfies following Expression 4: Nx≠Ny=Nz  [Expression 1] Nx=Nz≠Ny  [Expression 2] Nx≠Ny<Nz  [Expression 3] Nx≠Ny>Nz  [Expression 4] wherein Nx, Ny and Nz respectively refer to a refractive index of an x-axis direction, a refractive index of a y-axis direction, and a refractive index of a z-axis direction of the positive uniaxial phase retardation layer, the negative uniaxial phase retardation layer, the positive biaxial phase retardation layer, or the negative biaxial phase retardation layer, and “z-axis”refers to a thickness direction of the optical anisotropic layer, “x-axis” refers to a direction parallel to the slow axis of the optical anisotropic layer, and “y-axis” refers to a direction parallel to the fast axis of the optical anisotropic layer; wherein the laminate satisfies Expressions 5 to 7: | R 1 (λ)|>| R 2 (λ)|  [Expression 5] R 1 (λ)/ R 1 (550) < R 2 (λ)/ R 2 (550), when λ is not 550 nm   [Expression 6] R (450)/ R (550)< R (650)/ R (550)  [Expression 7] wherein |R 1 (λ)| represents an absolute value of an in-plane phase difference of one of the positive biaxial phase retardation layer and the optical anisotropic layer with respect to light having a wavelength of λ nm; |R 2 (λ)| represents an absolute value of an in-plane phase difference of the other of the positive biaxial phase retardation layer and the optical anisotropic layer with respect to light having the wavelength of λ nm; R 1 (λ) and R 1 (550) represent in-plane phase differences with respect to light having the wavelength of λ nm and 550 nm, respectively, of the layer having |R 1 (λ)| in Expression 5; R 2 (λ) and R 2 (550) represent in-plane differences with respect to light having the wavelength of λ, nm and 550 nm, respectively, of the layer having |R 2 (λ)| in Expression 5; and R(450), R(550), and R(650) represent in-plane phase differences of the optical film with respect to light having a wavelength of 450 nm, 550 nm and 650 nm, respectively; and wherein R(550) is in a range from 100 nm to 250 nm. 2. The optical film of claim 1 , wherein the positive biaxial phase retardation layer has an in-plane phase difference of 200 nm to 290 nm with respect to light with a 550 nm wavelength. 3. The optical film of claim 1 , wherein a ratio (RT/RI) of the phase difference (RT) in thickness direction of the positive biaxial phase retardation layer to the in-plane phase difference (RI) of the positive biaxial phase retardation layer is greater than 0 and not more than 3. 4. The optical film of claim 1 , wherein the ratio (RT/RI) of the phase difference (RT) in thickness direction of the positive biaxial phase retardation layer to the in-plane phase difference (RI) of the positive biaxial phase retardation layer is greater than 0and not more than 1.1, and the optical anisotropic layer is a uniaxial phase retardation layer. 5. The optical film of claim 1 , wherein the ratio (RT/RI) of the phase difference (RT) in thickness direction of the positive biaxial phase retardation layer to the in-plane phase difference (RI) of the positive biaxial phase retardation layer is in a range of 0.3 to 1.1, and the optical anisotropic layer is a positive uniaxial phase retardation layer. 6. The optical film of claim 1 , wherein the ratio (RT/RI) of the phase difference (RT) in thickness direction of the positive biaxial phase retardation layer to the in-plane phase difference (RI) of the positive biaxial phase retardation layer is greater than 0 and not more than 1, and the optical anisotropic layer is a negative uniaxial phase retardation layer. 7. The optical film of claim 1 , wherein the ratio (RT/RI) of the phase difference (RT) in thickness direction of the positive biaxial phase retardation layer to the in-plane phase difference (RI) of the positive biaxial phase retardation layer is greater than 0and not more than 2, and the optical anisotropic layer is a biaxial phase retardation layer. 8. The optical film of claim 1 , wherein the ratio (RT/RI) of the phase difference (RT) in thickness direction of the positive biaxial phase retardation layer to the in-plane phase difference (RI) of the positive biaxial phase retardation layer is greater than 0 and not more than 1.5, and the optical anisotropic layer is a positive biaxial phase retardation layer. 9. The optical film of claim 1 , wherein the ratio (RT/RI) of the phase difference (RT) in thickness direction of the positive biaxial phase retardation layer to the in-plane phase difference (RI) of the positive biaxial phase retardation layer is greater than 0 and not more than 2, and the optical anisotropic layer is a negative biaxial phase retardation layer. 10. The optical film of claim 1 , wherein the optical anisotropic layer has an in-plane phase difference of 95 nm to 145 nm with respect to light with a 550 nm wavelength. 11. The optical film of claim 1 , wherein the optical anisotropic layer has a phase difference in thickness direction of −200 nm to 200 nm. 12. A polarizing plate which comprises a linear polarizer and the optical film of claim 1 . 13. The polarizing plate of claim 12 , wherein a light absorption axis of the linear polarizer and the optical axis of the positive biaxial phase retardation layer form an angle of 45 degrees. 14. A display device comprising the polarizing plate of claim 12 . 15. The display device of claim 14 , which is a reflective liquid crystal display device, a semi-transmissive/reflective liquid crystal display device or an organic light-emitting device. 16. The optical film of claim 1 , wherein the positive biaxial phase retardation layer and the optical anisotropic layer are separated by an adhesive, or separated by a pressure-sensitive adhesive. 17. The optical film of claim 1 , wherein R(450)/R(550) value is in a range of 0.81 to 0.99, and R(650)/R(550) value is in a range of 1.01 to 1.19.