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control greyscale image (Ocean Optics)

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Ocean Optics control greyscale image

Figure 1. Experimental protocol. (a-d) Different deﬁnition levels of the caustic animations. (a) Control (same-intensity <t>greyscale</t> image). (b) Low deﬁnition. (c) Medium deﬁnition. (d) High deﬁnition. (e-f) Schematic diagram of the experimental design. (e) Top view. (f) Frontal view. The brown line at the tank bottom in (f) depicts the printed photographs of a homogeneous sediment sample. C ¼ Camera; G ¼ Grass (artiﬁcial turf); P ¼ Projector; T ¼ Tubes, used to introduce prey items. (g) Timeline for any of the 12 caustic playbacks. All caustic playbacks started with a 10 min long greyscale acclimatization period, followed by a 30 s long transition (T) period inducing an 11 min long segment with the corresponding caustic condition. The shrimp was introduced into the tank after 11 min 30 s (blue dashed line), resulting in a 10 min period for the cuttleﬁsh to catch the shrimp under a caustic stimulus. (h) Timeline for the control playback. This playback consisted entirely of a greyscale image displayed throughout the trial.

Control Greyscale Image, supplied by Ocean Optics, used in various techniques. Bioz Stars score: 99/100, based on 12003 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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Average 99 stars, based on 12003 article reviews

control greyscale image - by Bioz Stars, 2026-04

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1) Product Images from "Visual noise from caustic flicker does not affect the hunting success of cuttlefish"

Article Title: Visual noise from caustic flicker does not affect the hunting success of cuttlefish

Journal: Animal Behaviour

doi: 10.1016/j.anbehav.2023.06.002

Figure 1. Experimental protocol. (a-d) Different deﬁnition levels of the caustic animations. (a) Control (same-intensity greyscale image). (b) Low deﬁnition. (c) Medium deﬁnition. (d) High deﬁnition. (e-f) Schematic diagram of the experimental design. (e) Top view. (f) Frontal view. The brown line at the tank bottom in (f) depicts the printed photographs of a homogeneous sediment sample. C ¼ Camera; G ¼ Grass (artiﬁcial turf); P ¼ Projector; T ¼ Tubes, used to introduce prey items. (g) Timeline for any of the 12 caustic playbacks. All caustic playbacks started with a 10 min long greyscale acclimatization period, followed by a 30 s long transition (T) period inducing an 11 min long segment with the corresponding caustic condition. The shrimp was introduced into the tank after 11 min 30 s (blue dashed line), resulting in a 10 min period for the cuttleﬁsh to catch the shrimp under a caustic stimulus. (h) Timeline for the control playback. This playback consisted entirely of a greyscale image displayed throughout the trial.

Figure Legend Snippet: Figure 1. Experimental protocol. (a-d) Different deﬁnition levels of the caustic animations. (a) Control (same-intensity greyscale image). (b) Low deﬁnition. (c) Medium deﬁnition. (d) High deﬁnition. (e-f) Schematic diagram of the experimental design. (e) Top view. (f) Frontal view. The brown line at the tank bottom in (f) depicts the printed photographs of a homogeneous sediment sample. C ¼ Camera; G ¼ Grass (artiﬁcial turf); P ¼ Projector; T ¼ Tubes, used to introduce prey items. (g) Timeline for any of the 12 caustic playbacks. All caustic playbacks started with a 10 min long greyscale acclimatization period, followed by a 30 s long transition (T) period inducing an 11 min long segment with the corresponding caustic condition. The shrimp was introduced into the tank after 11 min 30 s (blue dashed line), resulting in a 10 min period for the cuttleﬁsh to catch the shrimp under a caustic stimulus. (h) Timeline for the control playback. This playback consisted entirely of a greyscale image displayed throughout the trial.

Techniques Used: Control, Introduce

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Journal: Animal Behaviour

Article Title: Visual noise from caustic flicker does not affect the hunting success of cuttlefish

doi: 10.1016/j.anbehav.2023.06.002

Figure Lengend Snippet: Figure 1. Experimental protocol. (a-d) Different deﬁnition levels of the caustic animations. (a) Control (same-intensity greyscale image). (b) Low deﬁnition. (c) Medium deﬁnition. (d) High deﬁnition. (e-f) Schematic diagram of the experimental design. (e) Top view. (f) Frontal view. The brown line at the tank bottom in (f) depicts the printed photographs of a homogeneous sediment sample. C ¼ Camera; G ¼ Grass (artiﬁcial turf); P ¼ Projector; T ¼ Tubes, used to introduce prey items. (g) Timeline for any of the 12 caustic playbacks. All caustic playbacks started with a 10 min long greyscale acclimatization period, followed by a 30 s long transition (T) period inducing an 11 min long segment with the corresponding caustic condition. The shrimp was introduced into the tank after 11 min 30 s (blue dashed line), resulting in a 10 min period for the cuttleﬁsh to catch the shrimp under a caustic stimulus. (h) Timeline for the control playback. This playback consisted entirely of a greyscale image displayed throughout the trial.

Article Snippet: Spectral irradiance (mW/cm2 per nm) of the 12 caustic playbacks as well as the control greyscale image (uint8 value 1⁄4 87), measured with a spectrometer (USB2000) coupled to a 400 mm bare optic fibre (R400-7-UV-VIS) and calibrated using a calibrated light source (DH-2000; all Ocean Insight, Orlando, FL, U.S.A.) Figure A2.

Techniques: Control, Introduce

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