Churkin A.A., Kapustin V.V., Konyukhov D.S., Vladov M.L., 2021. Recent developments in Russian practice of normative regulation of technical geophysics. Geotechnics, Vol. XIII, No. 2, pp. 56–70, https://doi.org/10.25296/2221-5514-2021-13-2-56-70.
1. Vladov M.L., Kapustin V.V., Struchkov V.S., Kirilenko A.M., Znaychenko P.A., 2017. Application of seismoacoustic methods in the monitoring
system of hydrotechnical structures. Geotechnics, No. 5, pp. 32–42. (in Russian)
2. Volkov V.A., Vladov M.L., Kalinina A.V., Ammosov S.M., Graminovsky N.A., Kapustin V.V., Marchenkov A.Yu., 2019. Influence of vibration loads
on railway buildings and structures. Put i Putevoye Khozyaystvo, No. 7, pp. 31–33. (in Russian)
3. Istratov V.A., Kolbenkov A.V., Kuznetsov N.M., Perekalin S.O., Cherepanov A.O., 2019. The method of volumetric radio wave geointerroscopy of
rocks in the interwell space. The patent of the Russian Federation No. 2710874 dated March 27, 2019. (in Russian)
4. Istratov V.A., Skrinnik A.V., Perekalin S.O., Kolbenkov A.V., Cherepanov A.O., 2019. Method of dielectric logging of the near-wellbore space. The
patent of the Russian Federation No. 2714177 dated December 30, 2019. (in Russian)
5. Kapustin V.V., 2014. Monitoring of dynamic effects of transport systems on soil bodies. Engineering Survey, No. 11, pp. 34–39. (in Russian)
6. Kapustin V.V., Vladov M.L., 2020. Technical geophysics. Methods and tasks. Geotechnics, Vol. ХII, No. 4, pp. 72–85, https://doi.org/10.25296/2221-
5514-2020-12-4-72-85. (in Russian)
7. Kapustin V.V., Semeikin N.P., Monakhov V.V., Trushkov V.N., 2013. Hardware-methodical complex for measuring natural and technogenic vibration
fields. Seismic Technologies, No. 1, pp. 96–102. (in Russian)
8. Konukhov D.S., 2019. Technological safety of underground development in restrained urban conditions. Metro i Tonneli, No. 1, pp. 26–29. (in Russian)
9. Kuznetsov N.M., 2012. 3D processing method of crosshole radiowave investigation. Bulletin of Kamchatka Regional Association “Educational-Scientific
Center”. Earth Sciences, Issue19, No. 1, pp. 240–246. (in Russian)
10.Kuznetsov N.M., Kolbenkov A.V., Istratov V.A., Perekalin S.O., 2017. Program for processing radio wave transmission data by radio wave geointerroscopy
«RVGI#3D». Certificate of state registration of computer programs No. 2017662496 dated September 20, 2017. (in Russian)
11.Malinin A.G., 2010. Jet grouting of soils. Stroyizdat, Moscow. (in Russian)
12.Modin I.N., 2010. Electrical prospecting in technical and archaeological geophysics. DSc Thesis, Lomonosov Moscow State University, Moscow. (in Russian)
13.Mukhin A.A., Kapustin V.V., Churkin A.A., Lozovsky I.N., 2019. Technical regulation of pile integrity testing. Geotechnics, Vol. ХI, No. 2, pp. 80–89,
https://doi.org/10.25296/2221-5514-2019-11-2-80-89. (in Russian)
14.Mukhin A.A., Lozovsky I.N., Churkin A.A., 2019. AIGEOS LLC technical standards for the nondestructive pile integrity testing. Crosshole ultrasonic
logging. Geotechnics, Vol. ХI, No. 3, pp. 64–79, https://doi.org/10.25296/2221-5514-2019-11-3-64-79. (in Russian)
15.Mukhin A.A., Lozovsky I.N., Churkin A.A., 2019. AIGEOS LLC technical standards for the nondestructive pile integrity testing. Low strain impact method.
Geotechnics, Vol. ХI, No. 4, pp. 68–78. (in Russian)
16.Mukhin A.A., Lozovsky I.N., Churkin A.A., 2020. “AIGEOS” LLC technical standards for the nondestructive pile integrity testing. Thermal integrity
profiling method. Geotechnics, Vol. ХII, No. 1, pp. 74–86. (in Russian)
17.Nabatov V.V., Gaysin R.M., 2018. Handling of GPR data on voids in annular space. Gorny Informatsionno-Analiticheskiy Byulleten, No. 1, pp. 19–25,
https://doi.org/10.25018/0236-1493-2018-1-0-19-25. (in Russian)
18. Semenova A.A., Supilin M.A., Rodionova A.E., Rodionova M.E., 2011. Experience in the integrated application of vibroacoustic, thermometric and ground
penetrating radar control methods in the study of the state of the running tunnels of the Nizhny Novgorod metro. Gorny Informatsionno-Analiticheskiy
Byulleten, No. 8, pp. 219–223. (in Russian)
19.Khmelnitsky A.Yu., 2013. Experimental and theoretical study of wave movements in the pile-soil system in order to improve the acoustic method of pile
inspection. PhD Thesis, Lomonosov Moscow State University, Moscow. (in Russian)
20. Chernyakov A.V., Bogomolova O.V., Kapustin V.V., Vladov M.L., Kalinin V.V., 2008. Quality control of geotechnical constructions created by jet grouting.
Seismic Technologies, No. 3, pp. 97–103. (in Russian)
21. Chernyakov A.V., Bogomolova O.V., Kapustin V.V., Istratov V.A., Bobachev A.A., 2013. Using a complex of geophysical and geotechnical methods for
organization of quality control of “hidden” works and monitoring during large-scale urban construction. Geotechnics, No. 1, pp. 4–21. (in Russian)
22. Churkin A.A., 2020. Development of a methodology for using a geophysical complex for quality control of buried monolithic structures. PhD Thesis,
Lomonosov Moscow State University, Moscow, https://doi.org/10.13140/RG.2.2.15557.17122. (in Russian)
23. Churkin A.A., Lozovsky I.N., 2020. Quality assurance of diaphragm and pile walls by geophysics. Construction and Geotechnics, Vol. 11, No. 2, pp. 49–61,
https://doi.org/10.15593/2224-9826/2020.2.05. (in Russian)
24. Churkin A.A., Lozovsky I.N., Frolov V.E., Brovikov Yu.N., 2018. Complex study of bored piles quality on experimental site by nondestructive integrity
testing methods. Geotechnics, Vol. X, No. 5–6, pp. 72–83. (in Russian)
25. Sheinin V.I., Blokhin D.I., Gaisin R.M., Maksimovich Ig.B, Maksimovich Il.B., Khodarev V.V., 2015. Comprehensive diagnostics of the technical state of a
monolithic “wall in the ground” after long-term conservation. Osnovaniya, Fundamenty i Mehanika Gruntov, No. 4, pp. 19–24,
https://doi.org/10.1007/s11204-014-9277-5. (in Russian)
26.Amir J.M., Amir E.I., 2008. Critical comparison of ultrasonic pile testing standards. Proceedings of 8th International Conference on application of stress wave
theory to piling, Lisbon, Portugal, 2008, pp. 453–459.
27.Amir J.M., 2017. Pile integrity testing: history, present situation and future agenda. Proceedings of 3rd Bolivian International Conference deep foundations,
Santa Cruz de la Sierra, Bolivia, 2017, pp. 17–32.
28. Camp III W.M., Holley D.W., Canivan G.J., 2007. Crosshole sonic logging of South Carolina drilled shafts: a five-year summary. Proceedings of ASCE Geo
Denver 2007, Denver, CO, USA, 2017, рр. 1–11.
29. Brettmann T., Hertlein B., Whitmire B., Meyer M., 2012. Guideline for interpretation of nondestructive integrity testing of augered cast-in-place and drilled
displacement piles. Publishing house of the Deep Foundations Institute, Hawthorne, NJ, USA.
30.Konyukhov D.S., Polyankin A.G., 2019. Ensuring the safety of the existing buildings during the construction of the underground in Moscow. Proceedings of
the WTC 2019 ITA-AITES World tunnel Congress (WTC 2019), Naples, Italy, 2019, рр. 5756–5766, https://doi.org/10.1201/9780429424441-609.
31. Piscsalko G., Likins G., Mullins G., 2016. Drilled shaft acceptance criteria based upon thermal integrity profiling. Proceedings of DFI 41st Annual Conference
on deep foundations, New York, NY, USA, 2016, pp. 1–10.
32. Sellountou A. E., Amir J.M., Canivan G., Chernauskas L., Hertlein B., Kandaris P., Kovacs T., Likins G., 2019. Terminology and evaluation criteria of
crosshole sonic logging (CSL) as applied to deep foundations. Publishing house of the Deep Foundations Institute, Hawthorne, NJ, USA.
33.Wightman W.E., Jalinoos F., Sirles P., Hanna K., 2004. Application of geophysical methods to highway related problems. Publishing house of the
Federal Highway Administration, Lakewood, CO, USA.