正文
From 史家胡同:
不太相信高像素的分辨率優勢這麽快就完全消失了,衍射會減少分辨率,但是什麽時候完全抵消?是不是跟鏡頭和眼神兒有關。。。我隻相信真圖,要是有人直接拿一個7D和350D在f11的圖來對比就好了。
Photozone有同一個鏡頭在350D(8MP)和50D(15MP)上的評測,即使在f11,50D的15MP也是在resolution上勝出一籌,比如Canon 10-22,在f11,14mm焦距,在350D上中心resolution是1909,在50D上就是2206.5,明顯高出很多。其他鏡頭也一樣。
In other words, even at small aperture, beyond diffraction limit, lab tests show higher camera resolution still helps with picture resolution. Why?
The reason:
The final resolution (picture resolution) is a convolution of the lens resolution and the sensor resolution. Rigorously speaking, this is an integration. For simple cases (either zero or one), you can approximate the picture resolution qualitatively (note, only qualitatively, but the trend is correct) in the following way:
1/P = 1/L + 1/C
where P is the final picture resolution in lines per mm, L is the lens resolution, C is the camera resolution.
Case 1: If L=3, C=3 (camera resolution matches lens resolution), then P=1.5
Case 2: Increase the camera resolution to C=4 (beyond lens resolution), then, P=1.7, resulting in better picture resolution than Case 1.
Case 3: Increase C to infinity, then, P=L, resulting in picture resolution equal to the lens resolution. This is the maximum resolution you can achieve classically (by human eyes).
Case 4: Rayleigh criterion is meant for human eyes: Rayleigh decided that human eyes cannot see intensity variations less than 20%. But a CCD can detect 20% intensity variations without any problem. So numerical analysis can extract additional resolution beyond the lens resolution. This has been done in the Hubble Space Telescope case, about 15 years ago.
不太相信高像素的分辨率優勢這麽快就完全消失了,衍射會減少分辨率,但是什麽時候完全抵消?是不是跟鏡頭和眼神兒有關。。。我隻相信真圖,要是有人直接拿一個7D和350D在f11的圖來對比就好了。
Photozone有同一個鏡頭在350D(8MP)和50D(15MP)上的評測,即使在f11,50D的15MP也是在resolution上勝出一籌,比如Canon 10-22,在f11,14mm焦距,在350D上中心resolution是1909,在50D上就是2206.5,明顯高出很多。其他鏡頭也一樣。
In other words, even at small aperture, beyond diffraction limit, lab tests show higher camera resolution still helps with picture resolution. Why?
The reason:
The final resolution (picture resolution) is a convolution of the lens resolution and the sensor resolution. Rigorously speaking, this is an integration. For simple cases (either zero or one), you can approximate the picture resolution qualitatively (note, only qualitatively, but the trend is correct) in the following way:
1/P = 1/L + 1/C
where P is the final picture resolution in lines per mm, L is the lens resolution, C is the camera resolution.
Case 1: If L=3, C=3 (camera resolution matches lens resolution), then P=1.5
Case 2: Increase the camera resolution to C=4 (beyond lens resolution), then, P=1.7, resulting in better picture resolution than Case 1.
Case 3: Increase C to infinity, then, P=L, resulting in picture resolution equal to the lens resolution. This is the maximum resolution you can achieve classically (by human eyes).
Case 4: Rayleigh criterion is meant for human eyes: Rayleigh decided that human eyes cannot see intensity variations less than 20%. But a CCD can detect 20% intensity variations without any problem. So numerical analysis can extract additional resolution beyond the lens resolution. This has been done in the Hubble Space Telescope case, about 15 years ago.
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