{"payload":{"feedbackUrl":"https://github.com/orgs/community/discussions/53140","repo":{"id":29538397,"defaultBranch":"master","name":"sampling-investigations","ownerLogin":"johnpdmartin","currentUserCanPush":false,"isFork":false,"isEmpty":false,"createdAt":"2015-01-20T16:08:03.000Z","ownerAvatar":"https://avatars.githubusercontent.com/u/8399071?v=4","public":true,"private":false,"isOrgOwned":false},"refInfo":{"name":"","listCacheKey":"v0:1695767263.0","currentOid":""},"activityList":{"items":[{"before":"a0192c5d5f2853256c9e86c29d03a2d1817c9a57","after":"e7d5a64c185f4489d8b319d70a5868ee5e3d1259","ref":"refs/heads/master","pushedAt":"2024-05-15T22:41:05.000Z","pushType":"push","commitsCount":1,"pusher":{"login":"johnpdmartin","name":"John Martin","path":"/johnpdmartin","primaryAvatarUrl":"https://avatars.githubusercontent.com/u/8399071?s=80&v=4"},"commit":{"message":"added tau-(s) function perturbation results\n\nunder perturbation equation (13) the tau-(s) function has some examples where the non-trivial zeroes work not to crossover in sequence which is different from Riemann Zeta function under the same perturbation.","shortMessageHtmlLink":"added tau-(s) function perturbation results"}},{"before":"411a8af96a18c934b46e523ce43b411bdf1ebc0d","after":"a0192c5d5f2853256c9e86c29d03a2d1817c9a57","ref":"refs/heads/master","pushedAt":"2024-05-07T20:12:56.000Z","pushType":"push","commitsCount":1,"pusher":{"login":"johnpdmartin","name":"John Martin","path":"/johnpdmartin","primaryAvatarUrl":"https://avatars.githubusercontent.com/u/8399071?s=80&v=4"},"commit":{"message":"perturbation showing bad gram point behaviour\n\nlowering the symmetry of the dirichlet series function highlights the subtle difference near bad gram points and larger difference near Rosser rule violations for non-trivial zero behaviour.","shortMessageHtmlLink":"perturbation showing bad gram point behaviour"}},{"before":"dabdd5187e3e3664b4e3b717525235be5fb28a58","after":"411a8af96a18c934b46e523ce43b411bdf1ebc0d","ref":"refs/heads/master","pushedAt":"2024-05-03T16:19:29.000Z","pushType":"push","commitsCount":1,"pusher":{"login":"johnpdmartin","name":"John Martin","path":"/johnpdmartin","primaryAvatarUrl":"https://avatars.githubusercontent.com/u/8399071?s=80&v=4"},"commit":{"message":"updating fig 9, fixing typos\n\nfinished final calculation run for fig 9","shortMessageHtmlLink":"updating fig 9, fixing typos"}},{"before":"5cb1c8eb2acb754fb95499b851bec080914e5a45","after":"dabdd5187e3e3664b4e3b717525235be5fb28a58","ref":"refs/heads/master","pushedAt":"2024-04-23T20:37:58.000Z","pushType":"push","commitsCount":1,"pusher":{"login":"johnpdmartin","name":"John Martin","path":"/johnpdmartin","primaryAvatarUrl":"https://avatars.githubusercontent.com/u/8399071?s=80&v=4"},"commit":{"message":"precursor positions of non-trivial zeroes\n\nillustrates the precursor positions of non-trivial zeroes for zeta, L52, L53, 5-periodic tau+,5-periodic tau- functions for truncated Euler product and Dirichlet series approximations of full functions. In reality precursor non-trivial zeroes (are no longer present or) forced to the critical line for the full functions. 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