Simulated fluorescence process algorithm - Revision history

Citation bot: Add: pmid, authors 1-1. Removed parameters. Some additions/deletions were parameter name changes. | Use this bot. Report bugs. | Suggested by Dominic3203 | Category:Computer graphics algorithms | #UCB_Category 1/49

2024-11-29T13:53:42Z

Add: pmid, authors 1-1. Removed parameters. Some additions/deletions were parameter name changes. | Use this bot. Report bugs. | Suggested by Dominic3203 | Category:Computer graphics algorithms | #UCB_Category 1/49

← Previous revision		Revision as of 13:53, 29 November 2024
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	==Principle==		==Principle==

	The algorithm considers a virtual light source producing excitation light that illuminates the object. This casts shadows either on parts of the object itself or on other objects below it. The interaction between the excitation light and the object provokes the emission light, which also interacts with the object before it finally reaches the eye of the viewer.<ref>{{Cite journal \|~~last~~=Voort \|~~first~~=H. T. M. \|last2=Brakenhoff \|first2=G. J. \|last3=Baarslag \|first3=M. W. \|date=February 1989 \|title=Three-dimensional visualization methods for confocal microscopy \|url=http://dx.doi.org/10.1111/j.1365-2818.1989.tb00553.x \|journal=Journal of Microscopy \|volume=153 \|issue=2 \|pages=123–132 \|doi=10.1111/j.1365-2818.1989.tb00553.x \|issn=0022-2720}}</ref><ref>{{Cite journal \|~~last~~=Noordmans \|~~first~~=H.J. \|last2=van der Voort \|first2=H.T.M. \|last3=Smeulders \|first3=A.W.M. \|date=2000 \|title=Spectral volume rendering \|url=http://dx.doi.org/10.1109/2945.879782 \|journal=IEEE Transactions on Visualization and Computer Graphics \|volume=6 \|issue=3 \|pages=196–207 \|doi=10.1109/2945.879782 \|issn=1077-2626}}</ref>		The algorithm considers a virtual light source producing excitation light that illuminates the object. This casts shadows either on parts of the object itself or on other objects below it. The interaction between the excitation light and the object provokes the emission light, which also interacts with the object before it finally reaches the eye of the viewer.<ref>{{Cite journal \|last1=Voort \|first1=H. T. M. \|last2=Brakenhoff \|first2=G. J. \|last3=Baarslag \|first3=M. W. \|date=February 1989 \|title=Three-dimensional visualization methods for confocal microscopy \|url=http://dx.doi.org/10.1111/j.1365-2818.1989.tb00553.x \|journal=Journal of Microscopy \|volume=153 \|issue=2 \|pages=123–132 \|doi=10.1111/j.1365-2818.1989.tb00553.x \|pmid=2709405 \|issn=0022-2720}}</ref><ref>{{Cite journal \|last1=Noordmans \|first1=H.J. \|last2=van der Voort \|first2=H.T.M. \|last3=Smeulders \|first3=A.W.M. \|date=2000 \|title=Spectral volume rendering \|url=http://dx.doi.org/10.1109/2945.879782 \|journal=IEEE Transactions on Visualization and Computer Graphics \|volume=6 \|issue=3 \|pages=196–207 \|doi=10.1109/2945.879782 \|issn=1077-2626}}</ref>

	== See also ==		== See also ==

Roastedbeanz1: Adding/improving reference(s)

2024-03-03T20:02:29Z

Adding/improving reference(s)

← Previous revision		Revision as of 20:02, 3 March 2024
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	==Principle==		==Principle==

	The algorithm considers a virtual light source producing excitation light that illuminates the object. This casts shadows either on parts of the object itself or on other objects below it. The interaction between the excitation light and the object provokes the emission light, which also interacts with the object before it finally reaches the eye of the viewer.<ref>{{Cite journal \|last=Voort \|first=H. T. M. \|last2=Brakenhoff \|first2=G. J. \|last3=Baarslag \|first3=M. W. \|date=1989~~-02~~ \|title=Three-dimensional visualization methods for confocal microscopy \|url=http://dx.doi.org/10.1111/j.1365-2818.1989.tb00553.x \|journal=Journal of Microscopy \|volume=153 \|issue=2 \|pages=123–132 \|doi=10.1111/j.1365-2818.1989.tb00553.x \|issn=0022-2720}}</ref><ref>{{Cite journal \|last=Noordmans \|first=H.J. \|last2=van der Voort \|first2=H.T.M. \|last3=Smeulders \|first3=A.W.M. \|date=2000 \|title=Spectral volume rendering \|url=http://dx.doi.org/10.1109/2945.879782 \|journal=IEEE Transactions on Visualization and Computer Graphics \|volume=6 \|issue=3 \|pages=196–207 \|doi=10.1109/2945.879782 \|issn=1077-2626}}</ref>		The algorithm considers a virtual light source producing excitation light that illuminates the object. This casts shadows either on parts of the object itself or on other objects below it. The interaction between the excitation light and the object provokes the emission light, which also interacts with the object before it finally reaches the eye of the viewer.<ref>{{Cite journal \|last=Voort \|first=H. T. M. \|last2=Brakenhoff \|first2=G. J. \|last3=Baarslag \|first3=M. W. \|date=February 1989 \|title=Three-dimensional visualization methods for confocal microscopy \|url=http://dx.doi.org/10.1111/j.1365-2818.1989.tb00553.x \|journal=Journal of Microscopy \|volume=153 \|issue=2 \|pages=123–132 \|doi=10.1111/j.1365-2818.1989.tb00553.x \|issn=0022-2720}}</ref><ref>{{Cite journal \|last=Noordmans \|first=H.J. \|last2=van der Voort \|first2=H.T.M. \|last3=Smeulders \|first3=A.W.M. \|date=2000 \|title=Spectral volume rendering \|url=http://dx.doi.org/10.1109/2945.879782 \|journal=IEEE Transactions on Visualization and Computer Graphics \|volume=6 \|issue=3 \|pages=196–207 \|doi=10.1109/2945.879782 \|issn=1077-2626}}</ref>

	== See also ==		== See also ==

Roastedbeanz1: Ref fill. Clean up

2024-03-03T20:02:09Z

Ref fill. Clean up

← Previous revision		Revision as of 20:02, 3 March 2024
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	{{no footnotes\|date=December 2010}}		{{no footnotes\|date=December 2010}}
			{{Short description\|Computing algorithm}}

	The '''Simulated Fluorescence Process''' (SFP) is a computing [[algorithm]] used for [[scientific visualization]] of [[3D scanning\|3D data]] from, for example, [[fluorescence microscope]]s. By [[Computer simulation\|modeling]] a physical light/matter interaction process, an image can be computed which shows the data as it would have appeared in reality when viewed under these conditions.		The '''Simulated Fluorescence Process''' (SFP) is a computing [[algorithm]] used for [[scientific visualization]] of [[3D scanning\|3D data]] from, for example, [[fluorescence microscope]]s. By [[Computer simulation\|modeling]] a physical light/matter interaction process, an image can be computed which shows the data as it would have appeared in reality when viewed under these conditions.

	==Principle==		==Principle==

	The algorithm considers a virtual light source producing excitation light that illuminates the object. This casts shadows either on parts of the object itself or on other objects below it. The interaction between the excitation light and the object provokes the emission light, which also interacts with the object before it finally reaches the eye of the viewer.		The algorithm considers a virtual light source producing excitation light that illuminates the object. This casts shadows either on parts of the object itself or on other objects below it. The interaction between the excitation light and the object provokes the emission light, which also interacts with the object before it finally reaches the eye of the viewer.<ref>{{Cite journal \|last=Voort \|first=H. T. M. \|last2=Brakenhoff \|first2=G. J. \|last3=Baarslag \|first3=M. W. \|date=1989-02 \|title=Three-dimensional visualization methods for confocal microscopy \|url=http://dx.doi.org/10.1111/j.1365-2818.1989.tb00553.x \|journal=Journal of Microscopy \|volume=153 \|issue=2 \|pages=123–132 \|doi=10.1111/j.1365-2818.1989.tb00553.x \|issn=0022-2720}}</ref><ref>{{Cite journal \|last=Noordmans \|first=H.J. \|last2=van der Voort \|first2=H.T.M. \|last3=Smeulders \|first3=A.W.M. \|date=2000 \|title=Spectral volume rendering \|url=http://dx.doi.org/10.1109/2945.879782 \|journal=IEEE Transactions on Visualization and Computer Graphics \|volume=6 \|issue=3 \|pages=196–207 \|doi=10.1109/2945.879782 \|issn=1077-2626}}</ref>

	== See also ==		== See also ==
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	==References==		==References==
			{{Reflist}}

	H. T. M. van der Voort, G. J. Brakenhoff and M. W. Baarslag. "[https://onlinelibrary.wiley.com/doi/pdf/10.1111/j.1365-2818.1989.tb00553.x Three-dimensional visualization methods for confocal microscopy]", Journal of Microscopy, Vol. 153, Pt 2, February 1989, pp. 123–132.

	Noordmans, Herke Jan, Hans TM van der Voort, and Arnold WM Smeulders. "[https://ieeexplore.ieee.org/abstract/document/879782/ Spectral volume rendering]." IEEE transactions on visualization and computer graphics 6.3 (2000): 196–207.

	==External links==		==External links==
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	[[Category:Microscopy]]		[[Category:Microscopy]]
	[[Category:Fluorescence]]		[[Category:Fluorescence]]


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2022-07-14T23:07:34Z

External links

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JJMC89 bot III: Moving :Category:Visualization (graphic) to :Category:Visualization (graphics) per Wikipedia:Categories for discussion/Speedy

2022-04-19T05:53:12Z

Moving Category:Visualization (graphic) to Category:Visualization (graphics) per Wikipedia:Categories for discussion/Speedy

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	[[Category:Computer graphics algorithms]]		[[Category:Computer graphics algorithms]]
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	[[Category:Microscopes]]		[[Category:Microscopes]]
	[[Category:Microscopy]]		[[Category:Microscopy]]

Goszei: General fixes, removed underlinked tag

2021-06-23T02:48:05Z

General fixes, removed underlinked tag

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	{{multiple issues\|
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	{{no footnotes\|date=December 2010}}		{{no footnotes\|date=December 2010}}
	}}

	The '''Simulated Fluorescence Process''' (SFP) is a computing [[algorithm]] used for [[scientific visualization]] of [[3D scanning\|3D data]] from, for example, [[fluorescence microscope]]s. By [[Computer simulation\|modeling]] a physical light/matter interaction process, an image can be computed which shows the data as it would have appeared in reality when viewed under these conditions.		The '''Simulated Fluorescence Process''' (SFP) is a computing [[algorithm]] used for [[scientific visualization]] of [[3D scanning\|3D data]] from, for example, [[fluorescence microscope]]s. By [[Computer simulation\|modeling]] a physical light/matter interaction process, an image can be computed which shows the data as it would have appeared in reality when viewed under these conditions.
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	The algorithm considers a virtual light source producing excitation light that illuminates the object. This casts shadows either on parts of the object itself or on other objects below it. The interaction between the excitation light and the object provokes the emission light, which also interacts with the object before it finally reaches the eye of the viewer.		The algorithm considers a virtual light source producing excitation light that illuminates the object. This casts shadows either on parts of the object itself or on other objects below it. The interaction between the excitation light and the object provokes the emission light, which also interacts with the object before it finally reaches the eye of the viewer.

	== See ~~Also~~ ==		== See also ==

	* [[Computer graphics lighting]]		* [[Computer graphics lighting]]

Tikwriter: some wikilinks, some "see also" links

2021-06-21T21:43:51Z

some wikilinks, some "see also" links

← Previous revision		Revision as of 21:43, 21 June 2021
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	}}		}}

	The '''Simulated Fluorescence Process''' (SFP) is a computing algorithm used for [[scientific visualization]] of 3D data from, for example, [[fluorescence microscope]]s. By modeling a physical light/matter interaction process, an image is computed ~~showing~~ the data as it would have appeared in reality when viewed under these conditions.		The '''Simulated Fluorescence Process''' (SFP) is a computing [[algorithm]] used for [[scientific visualization]] of [[3D scanning\|3D data]] from, for example, [[fluorescence microscope]]s. By [[Computer simulation\|modeling]] a physical light/matter interaction process, an image can be computed which shows the data as it would have appeared in reality when viewed under these conditions.

	==Principle==		==Principle==

	The algorithm considers a virtual light source producing excitation light that illuminates the object. This casts shadows either on parts of the object itself or on other objects below it. The interaction between the excitation light and the object provokes the emission light, which also interacts with the object before it finally reaches the eye of the viewer.		The algorithm considers a virtual light source producing excitation light that illuminates the object. This casts shadows either on parts of the object itself or on other objects below it. The interaction between the excitation light and the object provokes the emission light, which also interacts with the object before it finally reaches the eye of the viewer.

			== See Also ==

			* [[Computer graphics lighting]]
			* [[Rendering (computer graphics)]]

	==References==		==References==

Wikiacc: unwarranted removal of maintenance template

2021-01-20T01:24:45Z

unwarranted removal of maintenance template

← Previous revision		Revision as of 01:24, 20 January 2021
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			{{multiple issues\|

			{{Underlinked\|date=March 2015}}
	{{no footnotes\|date=December 2010}}		{{no footnotes\|date=December 2010}}
			}}


	The '''Simulated Fluorescence Process''' (SFP) is a computing algorithm used for [[scientific visualization]] of 3D data from, for example, [[fluorescence microscope]]s. By modeling a physical light/matter interaction process, an image is computed showing the data as it would have appeared in reality when viewed under these conditions.		The '''Simulated Fluorescence Process''' (SFP) is a computing algorithm used for [[scientific visualization]] of 3D data from, for example, [[fluorescence microscope]]s. By modeling a physical light/matter interaction process, an image is computed showing the data as it would have appeared in reality when viewed under these conditions.

!matt5454!matt at 18:35, 17 January 2021

2021-01-17T18:35:24Z

← Previous revision		Revision as of 18:35, 17 January 2021
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	{{multiple issues\|
	{{Underlinked\|date=March 2015}}
	{{no footnotes\|date=December 2010}}		{{no footnotes\|date=December 2010}}

	}}

	The '''Simulated Fluorescence Process''' (SFP) is a computing algorithm used for [[scientific visualization]] of 3D data from, for example, [[fluorescence microscope]]s. By modeling a physical light/matter interaction process, an image is computed showing the data as it would have appeared in reality when viewed under these conditions.		The '''Simulated Fluorescence Process''' (SFP) is a computing algorithm used for [[scientific visualization]] of 3D data from, for example, [[fluorescence microscope]]s. By modeling a physical light/matter interaction process, an image is computed showing the data as it would have appeared in reality when viewed under these conditions.

I dream of horses: clean up, typo(s) fixed: 196-207 → 196–207

2020-11-02T06:59:14Z

clean up, typo(s) fixed: 196-207 → 196–207

← Previous revision		Revision as of 06:59, 2 November 2020
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	H. T. M. van der Voort, G. J. Brakenhoff and M. W. Baarslag. "[https://onlinelibrary.wiley.com/doi/pdf/10.1111/j.1365-2818.1989.tb00553.x Three-dimensional visualization methods for confocal microscopy]", Journal of Microscopy, Vol. 153, Pt 2, February 1989, pp. 123–132.		H. T. M. van der Voort, G. J. Brakenhoff and M. W. Baarslag. "[https://onlinelibrary.wiley.com/doi/pdf/10.1111/j.1365-2818.1989.tb00553.x Three-dimensional visualization methods for confocal microscopy]", Journal of Microscopy, Vol. 153, Pt 2, February 1989, pp. 123–132.

	Noordmans, Herke Jan, Hans TM van der Voort, and Arnold WM Smeulders. "[https://ieeexplore.ieee.org/abstract/document/879782/ Spectral volume rendering]." IEEE transactions on visualization and computer graphics 6.3 (2000): ~~196-207~~.		Noordmans, Herke Jan, Hans TM van der Voort, and Arnold WM Smeulders. "[https://ieeexplore.ieee.org/abstract/document/879782/ Spectral volume rendering]." IEEE transactions on visualization and computer graphics 6.3 (2000): 196–207.

	==External links==		==External links==
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