Visual sensitivity, blur and the sources of variability in the amplitude spectra of natural scenes

Field, David; Brady, Nuala

doi:10.1016/s0042-6989(97)00181-8

Cited by 221 publications

(184 citation statements)

References 32 publications

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“…This is because structural information at the object level becomes finer in spatial terms as the object moves farther away, gradually slipping below the acuity limit of the observer. Also, in natural images, low spatial frequencies have much higher contrast levels, with the energy dropping off as a 1/f n function, where f is frequency and n is an exponent between about 1.1 and 2.2 (see, e.g., Field & Brady, 1997;Rainville & Kingdom, 1999). This means that obscuration that reduces contrast-such as glare or fog-will tend to affect the higher frequencies more.…”

Section: Discussionmentioning

confidence: 99%

Subordinate-level categorization relies on high spatial frequencies to a greater degree than basic-level categorization

Collin

McMullen

2005

Perception & Psychophysics

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Section: Discussionmentioning

confidence: 99%

Subordinate-level categorization relies on high spatial frequencies to a greater degree than basic-level categorization

Collin

McMullen

2005

Perception & Psychophysics

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“…Boutet et al (2003) suggested, instead, that the middleband advantage might be due to the middle range of frequencies having sufficient amounts of both contrast and spatial information to be useful. The contrast in a natural image drops as 1/f n , where f is frequency and n is an exponent in the range of about 1-2 (Field & Brady, 1997). This means that the amount of contrast in a natural image is halved for every doubling of frequency.…”

Section: Discussionmentioning

confidence: 99%

Spatial frequency thresholds for face recognition when comparison faces are filtered and unfiltered

Collin

Therrien

Martin

et al. 2006

Perception & Psychophysics

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A number of studies have presented evidence that middle spatial frequencies (SFs), between about 8 and 16 cycles per face width (c/fw), provide information that is more useful for face recognition than are other frequency ranges (Bachmann, 1991;Costen, Parker, & Craw, 1994Gold, Bennett, & Sekuler, 1999;Näsänen, 1999;Parker & Costen, 2001;Rolls, Baylis, & Hasselmo, 1987). On the basis of these data, it has been suggested that band-pass spatial filtering may be the first stage of feature extraction during visual recognition (Näsänen, 1999). That is, the visual information reaching purported face recognition areas might be filtered to preferentially represent middle SFs. In the extreme, it is possible that visual information reaching face recognition areas of the brain is first reduced to only middle SF ranges prior to further analysis. In theory, this filtering could help to minimize the processing load placed on face recognition mechanisms by discarding low and high SFs.A few recent studies have cast doubt on the idea of an absolute advantage for middle SFs in face recognition by showing that recognition performance is little affected by the range of frequencies contained in face stimuli, so long as both comparison and test stimuli are filtered in the same way (Collin, Liu, Troje, McMullen, & Chaudhuri, 2004;Kornowski & Petersik, 2003;Liu, Collin, Rainville, & Chaudhuri, 2000). These findings seem incompatible with the idea that middle SFs provide the most useful information for face recognition. If this were the case, one would expect some degree of performance loss when attempting to match two faces that contain no SFs from inside the middle band, relative to matching two faces with SFs from within the middle band. However, this difference has not been observed. Instead, Collin and colleagues (Collin et al., 2004) have suggested that a broad range of SFs may be useful for any visual task and that the range will depend on such task characteristics as similarity between learned and tested stimuli. This is a view echoed by Schyns and colleagues (Schyns, 1998;Schyns & Gosselin, 2003), who suggested that a wide range of SFs may be used in any given task and that there is a top-down control of which SFs are accessed in an image.In the following, we first will discuss two sets of studies that respectively provide evidence for and against the idea of a middle-band advantage in face recognition. We then will present a pair of experiments that examined how the differing task demands of these two sets of studies might lead to different conclusions about the role of SFs in face recognition.Rolls and colleagues (Rolls et al., 1987) provided some of the earliest evidence that face recognition might rely preferentially on middle SFs. They recorded activity of face-sensitive neurons in the macaque superior sulcus in response to band-pass filtered face images. They found that these neurons responded most strongly to images containing frequencies between 4 and 32 c/fw. Bachmann (1991) provided the first clue that these physiolog...

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“…The limitations of this research can be a subjective judgment of photographs, limited number of photographs examined, and some data accuracy in pixel counting. There have been also several other studies applied fractal dimension such as evaluating the texture discrimination (Keller et al, 1989) and observing luminance patterns in natural scenes (Field and Brady, 1997). We therefore suggest that these techniques may be useful for future studies of investigating visual quality assessment of understory vegetation cover by applying box-counting method and FD which may also elucidate spatial data acquisition techniques in the future.…”

Section: Figurementioning

confidence: 94%

A New Method for Evaluating the Visual Quality of Loblolly Pine (Pinus Taeda L.) Forest

Atasoy

Kush

2018

SIJMAS

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Visual sensitivity, blur and the sources of variability in the amplitude spectra of natural scenes

Cited by 221 publications

References 32 publications

Subordinate-level categorization relies on high spatial frequencies to a greater degree than basic-level categorization

Subordinate-level categorization relies on high spatial frequencies to a greater degree than basic-level categorization

Spatial frequency thresholds for face recognition when comparison faces are filtered and unfiltered

A New Method for Evaluating the Visual Quality of Loblolly Pine (Pinus Taeda L.) Forest

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