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  1. 2022

  2. Determination of Cavities Under the Concrete Slab Anchoring the Upper Slopes of the Novosibirsk Hydroelectric Power Station Using Standing Waves

    Fedin, K. V., Kolesnikov, Y. I. & Ngomayezwe, L., 2022, Processes in GeoMedia—Volume IV. Springer, p. 1-8 8 p. (Springer Geology).

    Research output: Chapter in Book/Report/Conference proceedingChapterResearchpeer-review

  3. 2021

  4. Способ определения участков коррозии труб методом выделения упругих стоячих волн из микросейсм

    Федин, К. В. & Гриценко, А. А., 27 Oct 2021, IPC No. G01V1/30, Роспатент - Федеральная служба по интеллектуальной собственности, Patent No. 2758249, Priority date 22 Mar 2021, Priority No. 2021107681

    Research output: PatentPatent for invention

  5. On the influence of seasonal changes in the resonant properties of surface soils on seismic safety of structures

    Kolesnikov, Y. I., Fedin, V. V. & Ngomayezwe, L., Oct 2021, In: Journal of Applied Geophysics. 193, 104412.

    Research output: Contribution to journalArticlepeer-review

  6. Способ определения плотности костной ткани на основе выделения стоячих волн из микросейсм периферического скелета

    Федин, К. В. & Климонтов, В. В., 7 Jul 2021, IPC No. A61B8/08, Роспатент - Федеральная служба по интеллектуальной собственности, Patent No. 2750976, Priority date 16 Oct 2020, Priority No. 2020134154

    Research output: PatentPatent for invention

  7. Способ экспресс-диагностики состояния устойчивости колонн газовых скважин методом стоячих волн

    Федин, К. В., 26 Mar 2021, IPC No. G01V1/00, G01V1/28, G01V1/30, Роспатент - Федеральная служба по интеллектуальной собственности, Patent No. 2745542, Priority date 27 Aug 2020, Priority No. 2020128623

    Research output: PatentPatent for invention

  8. Mapping of underground cavities by the passive seismic standing waves method: the case study of Barsukovskaya cave (Novosibirsk region, Russia)

    Fedin, K. V., Kolesnikov, Y. I. & Ngomayezwe, L., Jan 2021, In: Geophysical Prospecting. 69, 1, p. 167-179 13 p.

    Research output: Contribution to journalArticlepeer-review

  9. Determination of ice thickness using standing waves

    Fedin, K. V., Kolesnikov, Y. I. & Ngomayezwe, L., 2021, Springer Geology. Chaplina, T. (ed.). 1 ed. Springer, Vol. II. p. 9-13 5 p. (Springer Geology).

    Research output: Chapter in Book/Report/Conference proceedingChapterResearchpeer-review

  10. Determination of the condition of road coverings by acoustic noise data

    Fedin, K. V., Kolesnikov, Y. I. & Ngomayezwe, L., 2021, Springer Geology. Chaplina, T. (ed.). 1 ed. Springer, Vol. II. p. 1-4 4 p. (Springer Geology).

    Research output: Chapter in Book/Report/Conference proceedingChapterResearchpeer-review

  11. Diagnosis of the technical condition of standing wave support for pipeline

    Fedin, K. V., Kolesnikov, Y. I. & Ngomayezwe, L., 2021, Springer Geology. Chaplina, T. (ed.). 1 ed. Springer, Vol. II. p. 5-8 4 p. (Springer Geology).

    Research output: Chapter in Book/Report/Conference proceedingChapterResearchpeer-review

  12. 2020

  13. Compression waves reflection from the low-velocity azimuthally anisotropic medium: A physical model study

    Kolesnikov, Y., Fedin, K. V. & Ngomayezwe, L., May 2020, In: Geophysical Journal International. 221, 2, p. 1320-1326 7 p.

    Research output: Contribution to journalArticlepeer-review

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