Difference between revisions of "June 12, 2010"

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=Straightening the Circle=
 
=Straightening the Circle=
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<em>image by [mailto:From:jayem4646@eircom.net" rel="nofollow John Moore], Ireland</em><br />
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<em>image by [mailto:From:jayem4646@eircom.net John Moore], Ireland</em><br />
 
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Here are a few familiar views made unfamiliar using just a simple 'polar to rectangular' conversion (of the originals to the left). The top three show three craters that we're all used to seeing on LPOD, while the bottom three are recognisable maria. From most of the converted images, it can be seen how areas around the rim-floor, mountain-mare regions differ as a whole from, say, an imaginary straight line if drawn horizontally across them. While this conversion method of straightening circular features, like craters and maria, is just an experiment to see how they would look, I wonder if it would also have any application in the determination of impact-direction? As, is known, in some features the impact-direction can be determined by characteristic signatures, such as, the asymmetric appearance of craters e.g. Messier and Messier A, or the butterfly ray-pattern of, say, Proclus. However, while some features may look roundish when, in fact, they may not be as they may have slumping in their rims or missing serious gaps in their mountains/massifs etc., the detection of possible impact-directionality (if any should exists at all) would be hard. Might this method, therefore, be a way of measuring such events from this converted perspective? All one does is draw the above-mentioned, imaginary line across the full length of the straighened-out rim-floor, mountain-mare part, to see how it deviates above or below it. So, for example, if the impactor struck the surface mostly perpendicularly, the deviation from linearity wouldn't be that much, however, if it struck obliquely, it would be different - taking on a more wavey form (see bottom graphic). All that said, the above method may not be of any scientific use, and I am sure it has been well thought of before as a means for impact-direction, however, it still is an unusual way to 'see' features in this way. <br />
 
Here are a few familiar views made unfamiliar using just a simple 'polar to rectangular' conversion (of the originals to the left). The top three show three craters that we're all used to seeing on LPOD, while the bottom three are recognisable maria. From most of the converted images, it can be seen how areas around the rim-floor, mountain-mare regions differ as a whole from, say, an imaginary straight line if drawn horizontally across them. While this conversion method of straightening circular features, like craters and maria, is just an experiment to see how they would look, I wonder if it would also have any application in the determination of impact-direction? As, is known, in some features the impact-direction can be determined by characteristic signatures, such as, the asymmetric appearance of craters e.g. Messier and Messier A, or the butterfly ray-pattern of, say, Proclus. However, while some features may look roundish when, in fact, they may not be as they may have slumping in their rims or missing serious gaps in their mountains/massifs etc., the detection of possible impact-directionality (if any should exists at all) would be hard. Might this method, therefore, be a way of measuring such events from this converted perspective? All one does is draw the above-mentioned, imaginary line across the full length of the straighened-out rim-floor, mountain-mare part, to see how it deviates above or below it. So, for example, if the impactor struck the surface mostly perpendicularly, the deviation from linearity wouldn't be that much, however, if it struck obliquely, it would be different - taking on a more wavey form (see bottom graphic). All that said, the above method may not be of any scientific use, and I am sure it has been well thought of before as a means for impact-direction, however, it still is an unusual way to 'see' features in this way. <br />
 
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<br />
<em>[mailto:From:jayem4646@eircom.net" rel="nofollow John Moore]</em><br />
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<em>[mailto:From:jayem4646@eircom.net John Moore]</em><br />
 
<br />
 
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<strong>Technical Details</strong><br />
 
<strong>Technical Details</strong><br />
Features shown: (1) [http://the-moon.wikispaces.com/Sinus+Iridum Sinus Iridum] (Photo - Paolo R Lazzarotti). (2) [http://the-moon.wikispaces.com/Plato Plato] (Photo - Damian Peach). (3) [http://the-moon.wikispaces.com/Copernicus Copernicus] (Photo - Stefan Lammel). (4) [http://the-moon.wikispaces.com/Mare+Imbrium Mare Imbrium] (Selene Crustal Topo overlay on LDEM 64 - generated by LTVT). (5) [http://the-moon.wikispaces.com/Mare+Nectaris Mare Nectaris] (Selene Crustal Topo overlay on LDEM 64 - generated by LTVT). (6) [http://the-moon.wikispaces.com/Mare+Orientale Mare Orientale] (LOLA overlay on LDEM 64 - generated by LTVT).<br />
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Features shown: (1) [https://the-moon.us/wiki/Sinus_Iridum Sinus Iridum] (Photo - Paolo R Lazzarotti). (2) [https://the-moon.us/wiki/Plato Plato] (Photo - Damian Peach). (3) [https://the-moon.us/wiki/Copernicus Copernicus] (Photo - Stefan Lammel). (4) [https://the-moon.us/wiki/Mare_Imbrium Mare Imbrium] (Selene Crustal Topo overlay on LDEM 64 - generated by LTVT). (5) [https://the-moon.us/wiki/Mare_Nectaris Mare Nectaris] (Selene Crustal Topo overlay on LDEM 64 - generated by LTVT). (6) [https://the-moon.us/wiki/Mare_Orientale Mare Orientale] (LOLA overlay on LDEM 64 - generated by LTVT).<br />
 
Photoshop (Filter/Distort/Polar Coordinates).<br />
 
Photoshop (Filter/Distort/Polar Coordinates).<br />
 
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<br />
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<p><b>Yesterday's LPOD:</b> [[June 11, 2010|A Hole with No Sides?]] </p>
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<p><b>Tomorrow's LPOD:</b> [[June 13, 2010|Capelling Gash]] </p>
 
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Latest revision as of 17:50, 13 October 2018

Straightening the Circle

LPOD-June12-10.jpg
image by John Moore, Ireland

Here are a few familiar views made unfamiliar using just a simple 'polar to rectangular' conversion (of the originals to the left). The top three show three craters that we're all used to seeing on LPOD, while the bottom three are recognisable maria. From most of the converted images, it can be seen how areas around the rim-floor, mountain-mare regions differ as a whole from, say, an imaginary straight line if drawn horizontally across them. While this conversion method of straightening circular features, like craters and maria, is just an experiment to see how they would look, I wonder if it would also have any application in the determination of impact-direction? As, is known, in some features the impact-direction can be determined by characteristic signatures, such as, the asymmetric appearance of craters e.g. Messier and Messier A, or the butterfly ray-pattern of, say, Proclus. However, while some features may look roundish when, in fact, they may not be as they may have slumping in their rims or missing serious gaps in their mountains/massifs etc., the detection of possible impact-directionality (if any should exists at all) would be hard. Might this method, therefore, be a way of measuring such events from this converted perspective? All one does is draw the above-mentioned, imaginary line across the full length of the straighened-out rim-floor, mountain-mare part, to see how it deviates above or below it. So, for example, if the impactor struck the surface mostly perpendicularly, the deviation from linearity wouldn't be that much, however, if it struck obliquely, it would be different - taking on a more wavey form (see bottom graphic). All that said, the above method may not be of any scientific use, and I am sure it has been well thought of before as a means for impact-direction, however, it still is an unusual way to 'see' features in this way.

John Moore

Technical Details
Features shown: (1) Sinus Iridum (Photo - Paolo R Lazzarotti). (2) Plato (Photo - Damian Peach). (3) Copernicus (Photo - Stefan Lammel). (4) Mare Imbrium (Selene Crustal Topo overlay on LDEM 64 - generated by LTVT). (5) Mare Nectaris (Selene Crustal Topo overlay on LDEM 64 - generated by LTVT). (6) Mare Orientale (LOLA overlay on LDEM 64 - generated by LTVT).
Photoshop (Filter/Distort/Polar Coordinates).

Yesterday's LPOD: A Hole with No Sides?

Tomorrow's LPOD: Capelling Gash



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