Modulation transfer function (MTF) metrology and interpretation for digital image capture devices has usually concentrated on mid- to high-frequency information, relative to the half-sampling frequency. These regions typically quantify characteristics and operations such as sharpening, limiting resolution, and aliasing. However, a potential wealth of low-frequency, visually significant information is often masked in existing measurement results because of spatial data truncation. For print or document scanners, this influences measurements in the spatial frequency range of 0 to 2.0 cycles/mm, where the effects of veiling flare, micro flare, and integrating cavity effect (ICE) often manifest themselves. Using a form of edge-gradient analysis based on slanted edges, we present a method for measurement of these characteristics. By carefully adapting this well-established technique, these phenomena can be quantified. We also show how, in many cases, these effects can be treated as other spread-function or device-MTF components. The theory and field metrology of several devices using the adapted technique are also presented.
[1]
K Rossmann,et al.
Truncation errors in calculating the MTF of radiographic screen-film systems from the line spread function.
,
1972,
Physics in medicine and biology.
[2]
Robert P. Herloski.
Analytical computation of integrating cavity effect
,
1998,
Other Conferences.
[3]
David A. Atchison,et al.
The eye and visual optical instruments: Image quality criteria
,
1997
.
[4]
Peter D. Burns,et al.
Refined Slanted-Edge Measurement from Practical Camera and Scanner Testing
,
2002,
PICS.
[5]
Peter D. Burns,et al.
Slanted-Edge MTF for Digital Camera and Scanner Analysis
,
2000,
PICS.
[6]
Stephen E. Reichenbach,et al.
Characterizing digital image acquisition devices
,
1991
.
[7]
James J. Jakubowski.
Methodology For Quantifying Flare In A Microdensitometer
,
1980
.