Galilean system is set at infinity, reading caps are used for reading (see table).Ocular and objective lenses have a high-quality, anti-reflection hard coating.Diffractive aspheric PXM® lightweight lens, cera-tec®
Galilean system is set at infinity, reading caps are used for reading (see table).Ocular and objective lenses have a high-quality, anti-reflection hard coating.Diffractive aspheric PXM® lightweight lens, cera-tec®
Galilean system is set at infinity, reading caps are used for reading (see table).Ocular and objective lenses have a high-quality, anti-reflection hard coating.Diffractive aspheric PXM® lightweight lens, cera-tec®
Galilean system is set at infinity, reading caps are used for reading (see table).Ocular and objective lenses have a high-quality, anti-reflection hard coating.Diffractive aspheric PXM® lightweight lens, cera-tec®
Galilean system is set at infinity, reading caps are used for reading (see table).Ocular and objective lenses have a high-quality, anti-reflection hard coating.Diffractive aspheric PXM® lightweight lens, cera-tec®
Galilean system is set at infinity, reading caps are used for reading (see table).Ocular and objective lenses have a high-quality, anti-reflection hard coating.Diffractive aspheric PXM® lightweight lens, cera-tec®
Galilean system is set at infinity, reading caps are used for reading (see table).Ocular and objective lenses have a high-quality, anti-reflection hard coating.Diffractive aspheric PXM® lightweight lens, cera-tec®
Galilean system is set at infinity, reading caps are used for reading (see table).Ocular and objective lenses have a high-quality, anti-reflection hard coating.Diffractive aspheric PXM® lightweight lens, cera-tec®
infinity, reading caps are used for reading (see table).Large 13° visual field.Ocular and objective lenses have a high-quality, anti-reflection hard coating.Product AccessoriesReading caps for Galilei 2.2
visual acuity. The determination of visual acuity is not only necessary for fitting glasses or contact lenses, but it also provides the basis for optimum selection and individual adjustment of magnifying vision
