[math-fun] alleged impressive fiber-optic accomplishment
NY Times today (26 June 2015) says Nikola Alic and others have successfully sent optical signals thru an optical fiber 7456 miles long, WITHOUT any "repeaters" along the way. Supposedly, the method involves understanding what kinds of transformations happen to the signal during transit, and pre-applying an approximately-inverse transformation. That causes the signal to be maximally easy to detect at the receiving end. E. Temprana, E. Myslivets, B.P.-P. Kuo, L. Liu, V. Ataie, N. Alic, S. Radic: Overcoming Kerr-induced capacity limit in optical fiber transmission Science 348,6242 (26 June 2015) 1445-1448 http://www.sciencemag.org/content/348/6242/1445 As far as I understand (this may have been hype, but probably not) semiconductor chip manufacturers trying to optically-lithograph ultrafine patterns, have for years all done a similar trick. That is, (a) light is transmitted thru an optical mask defining the pattern, then (b) hits photoresist on the chip, whch (c) polymerizes, then (d) chemical etching or whatever is used to generate the pattern on the chip. This process abcd causes the pattern you get to differ from the pattern on the mask via some transformation which is somewhat understood, and can be, and is, approximately inverted. Hence the picture they draw on the mask intentionally is NOT the same as the intended pattern on the chip. This is actually a harder mathematical problem since 2 or 3 or 4 dimensional, whereas the fiber problem presumably is only 1 or 2 dimensional.
The photolithography technique you describe, used in semiconductor fabrication, is called optical proximity correction: https://en.wikipedia.org/wiki/Optical_proximity_correction Tom Warren D Smith writes:
NY Times today (26 June 2015) says Nikola Alic and others have successfully sent optical signals thru an optical fiber 7456 miles long, WITHOUT any "repeaters" along the way.
Supposedly, the method involves understanding what kinds of transformations happen to the signal during transit, and pre-applying an approximately-inverse transformation. That causes the signal to be maximally easy to detect at the receiving end.
E. Temprana, E. Myslivets, B.P.-P. Kuo, L. Liu, V. Ataie, N. Alic, S. Radic: Overcoming Kerr-induced capacity limit in optical fiber transmission Science 348,6242 (26 June 2015) 1445-1448 http://www.sciencemag.org/content/348/6242/1445
As far as I understand (this may have been hype, but probably not) semiconductor chip manufacturers trying to optically-lithograph ultrafine patterns, have for years all done a similar trick. That is, (a) light is transmitted thru an optical mask defining the pattern, then (b) hits photoresist on the chip, whch (c) polymerizes, then (d) chemical etching or whatever is used to generate the pattern on the chip.
This process abcd causes the pattern you get to differ from the pattern on the mask via some transformation which is somewhat understood, and can be, and is, approximately inverted. Hence the picture they draw on the mask intentionally is NOT the same as the intended pattern on the chip. This is actually a harder mathematical problem since 2 or 3 or 4 dimensional, whereas the fiber problem presumably is only 1 or 2 dimensional.
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I ran numerical technologies, an early Palo Alto company that sold optical proximity correction software, for about six months in 1997, as the founder Buno Pati considered whether to quit his Harvard EE appointment to run it himself. He did, after his first semester, then came back to Palo Alto and the company eventually did an IPO. The algorithms for doing the correction were delightfully combinatorial in their implementation, but not so much that I was tempted to stay in it. Fun stuff though. On Friday, June 26, 2015, Tom Karzes <karzes@sonic.net> wrote:
The photolithography technique you describe, used in semiconductor fabrication, is called optical proximity correction:
https://en.wikipedia.org/wiki/Optical_proximity_correction
Tom
Warren D Smith writes:
NY Times today (26 June 2015) says Nikola Alic and others have successfully sent optical signals thru an optical fiber 7456 miles long, WITHOUT any "repeaters" along the way.
Supposedly, the method involves understanding what kinds of transformations happen to the signal during transit, and pre-applying an approximately-inverse transformation. That causes the signal to be maximally easy to detect at the receiving end.
E. Temprana, E. Myslivets, B.P.-P. Kuo, L. Liu, V. Ataie, N. Alic, S. Radic: Overcoming Kerr-induced capacity limit in optical fiber transmission Science 348,6242 (26 June 2015) 1445-1448 http://www.sciencemag.org/content/348/6242/1445
As far as I understand (this may have been hype, but probably not) semiconductor chip manufacturers trying to optically-lithograph ultrafine patterns, have for years all done a similar trick. That is, (a) light is transmitted thru an optical mask defining the pattern, then (b) hits photoresist on the chip, whch (c) polymerizes, then (d) chemical etching or whatever is used to generate the pattern on the chip.
This process abcd causes the pattern you get to differ from the pattern on the mask via some transformation which is somewhat understood, and can be, and is, approximately inverted. Hence the picture they draw on the mask intentionally is NOT the same as the intended pattern on the chip. This is actually a harder mathematical problem since 2 or 3 or 4 dimensional, whereas the fiber problem presumably is only 1 or 2 dimensional.
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-- Thane Plambeck tplambeck@gmail.com http://counterwave.com/
participants (3)
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Thane Plambeck -
Tom Karzes -
Warren D Smith