... -35mm f /2. ... ... -35mm f /4L ... ... -35mm f /2. ... ... -35mm f /2. ... ... -40mm f /4L ... ... -35mm f / 3.5 -4. ... ... -70mm f /2. ... ... -70mm f /2. ... ... -70mm f /4L ... ... -85mm f / 3.5 -4. ... EF 24-105mm f /4L ... ... -70mm f /2. ...
... 0.01 mm f = 17 mm T 5.6 ... 9.49 3.5 f = 25 mm T 5.6 ... 5.50 3.5 f = 35 mm T 5.6 ... 4.63 3.5 f = 50 mm T 5.6 ... 4.29 3.5 f = 90 mm T 5.6 ... 4.09 3.5 f = 120 mm T 5.6 ... 4.05 3.5 ... 0.01 mm f = 17 mm T 5.6
CN-E18-80 mm T4.4 L IS KAS S ... f = 18 ... T 5.6 ... f = 24 ... T 5.6 ... f = 35 ... T 5.6 ... f = 50 ... T 5.6 ... f = 80 ... T 5.6 ... CN-E18-80 mm T4.4 L IS KAS S ... f = 18 ... T 5.6 ... f = 24 ... T 5.6 ... f = 35 ... T 5.6 ... f = 50 ... T 5.6 ... f = 80 ... T 5.6
... 0.01 mm f = 50 f = 75 f = 100 f = 200 f = 500 f = 1000 ... 0.01 mm f = 50 x ... f = 75 x ... f = 100 x ... 475. 24 f = 200 x ... f = 500 x ... f = 1000 x ... ... 0.01 mm f = 50 ... 5.45 3.5 3.33 ... f = 75 ... 4.55 3.5 3.42 ... f = 100 ... 4.30 3.5 3.45 ... f = 200
N i t F f Figure 1 Showing on top left the sampling structure of a 4K image sensor and the Nyquist frequency associated with that sampling; the bottom image represents the spatial detail of a 4K Super 35 mm lens that can fulfill the resolution capability of that 4K image sensor ... 5 Figure 6 Showing the natural falloff of resolution at Picture center of a hypothetical 4Klens in comparison with the more rapid MTF falloff of the hypothetical 4K camera