Timeline for Integration on algebraic curves
Current License: CC BY-SA 4.0
8 events
| when toggle format | what | by | license | comment | |
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| Dec 29, 2023 at 20:33 | comment | added | David Lehavi | It’s hard to understand what exactly you are trying to compute. The differentials of both curves are related to the differentials of the respective planes via adjunction, and the differentials of the two planes are related by the exact sequence of differentials of blow ups (that would be your binational transformation). This is all rather explicit, but you didn’t say what you plan to integrate these differentials on. | |
| Sep 9, 2023 at 23:30 | comment | added | mxjia | @FrançoisBrunault Yes, you are right. I'm currently reading a reference book (A. I. Bobenko, C. Klein (eds.), Computational Approach to Riemann Surfaces, 2011) on this subject. Thank you. | |
| Sep 9, 2023 at 9:38 | comment | added | François Brunault | I think you need to specify which cycles in $C_1$ you wish to integrate over. | |
| Sep 9, 2023 at 1:39 | comment | added | mxjia | @FrançoisBrunault Numerical computation is sufficient. | |
| Sep 8, 2023 at 20:01 | comment | added | François Brunault | Do you mean an exact or numerical computation? | |
| Sep 8, 2023 at 9:05 | history | edited | Daniele Tampieri | CC BY-SA 4.0 |
Minor Math Jaxing (formula hyperlinking)
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| Sep 8, 2023 at 7:55 | review | Close votes | |||
| Sep 19, 2023 at 3:08 | |||||
| Sep 8, 2023 at 2:05 | history | asked | mxjia | CC BY-SA 4.0 |