Forskarpresentation
Mohammad Bagherbandi
Professor, ämnesansvarig lantmäteriteknik
Forskningsämne: Samhällsbyggnad
E-post: mohammad.bagherbandi@hig.se
Telefon: 026-64 84 19
AKTUELL FORSKNING
LÄS MER OM
Artiklar
Vetenskapliga artiklar, refereegranskade
Jouybari, A., Bagherbandi, M. & Nilfouroushan, F. (2021). Comparison of the strip- and block-wise aerial triangulation using different exterior orientation parameters weights. Journal of Spatial Science. 10.1080/14498596.2020.1871086
[Mer information]
Maciuk, K., Kudrys, J., Bagherbandi, M. & Bezmenov, I. (2020). A new method for quantitative and qualitative representation of the noises type in Allan (and related) variances. Earth Planets and Space, 72 (1). 10.1186/s40623-020-01328-6
[Mer information]
Gido, N., Bagherbandi, M. & Nilfouroushan, F. (2020). Localized subsidence zones in Gävle city detected by Sentinel-1 PSI and leveling data. Remote Sensing, 12 (16). 10.3390/rs12162629
[Mer information]
Amin, H., Bagherbandi, M. & Sjöberg, L. (2020). Quantifying barystatic sea-level change from satellite altimetry, GRACE and Argo observations over 2005–2016. Advances in Space Research, 65 (8), 1922-1940. 10.1016/j.asr.2020.01.029
[Mer information]
Shirazian, M., Jazireeyan, I. & Bagherbandi, M. (2020). Reality measure of the published GPS satellite ephemeris uncertainties. Journal of Spatial Science. 10.1080/14498596.2020.1746702
[Mer information]
Gido, N., Amin, H., Bagherbandi, M. & Nilfouroushan, F. (2020). Satellite Monitoring of Mass Changes and Ground Subsidence in Sudan’s Oil Fields Using GRACE and Sentinel-1 Data. Remote Sensing, 12 (11). 10.3390/rs12111792
[Mer information]
Sjöberg, L. & Bagherbandi, M. (2020). Upper mantle density and surface gravity change in Fennoscandia, determined from GRACE monthly data. Tectonophysics, 782-783. 10.1016/j.tecto.2020.228428
[Mer information]
Amin, H., Sjöberg, L. & Bagherbandi, M. (2019). A global vertical datum defined by the conventional geoid potential and the Earth ellipsoid parameters. Journal of Geodesy, 93 (10), 1943-1961. 10.1007/s00190-019-01293-3
[Mer information]
Gido, N., Bagherbandi, M. & Sjöberg, L. (2019). A gravimetric method to determine horizontal stress field due to flow in the mantle in Fennoscandia. Geosciences Journal, 23 (3), 377-389. 10.1007/s12303-018-0046-8
[Mer information]
Gido, N., Bagherbandi, M., Sjöberg, L. & Tenzer, R. (2019). Studying permafrost by integrating satellite and in situ data in the northern high-latitude regions. Acta Geophysica, 67 (2), 721-734. 10.1007/s11600-019-00276-4
[Mer information]
Baranov, A., Tenzer, R. & Bagherbandi, M. (2018). Combined Gravimetric–Seismic Crustal Model for Antarctica. Surveys in geophysics, 39 (1), 23-56. 10.1007/s10712-017-9423-5
[Mer information]
Baranov, A., Bagherbandi, M. & Tenzer, R. (2018). Combined Gravimetric-Seismic Moho Model of Tibet. Geosciences, 8 (12). 10.3390/geosciences8120461
[Mer information]
Tenzer, R., Foroughi, I., Sjöberg, L., Bagherbandi, M., Hirt, C. & Pitoňák, M. (2018). Definition of Physical Height Systems for Telluric Planets and Moons. Surveys in geophysics, 39 (3), 313-335. 10.1007/s10712-017-9457-8
[Mer information]
Tenzer, R., Chen, W., Baranov, A. & Bagherbandi, M. (2018). Gravity maps of Antarctic lithospheric structure from remote-sensing and seismic data. Pure and Applied Geophysics, 175 (6), 2181-2203. 10.1007/s00024-018-1795-z
[Mer information]
Bagherbandi, M., Bai, Y., Sjöberg, L., Tenzer, R., Abrehdary, M., Miranda, S. & Sanchez, J. (2017). Effect of the lithospheric thermal state on the Moho interface : a case study in South America. Journal of South American Earth Sciences, 76, 198-207. 10.1016/j.jsames.2017.02.010
[Mer information]
Tenzer, R., Bagherbandi, M., Chen, W. & Sjöberg, L. (2017). Global Isostatic Gravity Maps From Satellite Missions and Their Applications in the Lithospheric Structure Studies. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 10 (2), 549-561. 10.1109/JSTARS.2016.2556219
[Mer information]
Abrehdary, M., Lars, S., Bagherbandi, M. & Sampietro, D. (2017). Towards the Moho depth and Moho density contrast along with their uncertainties from seismic and satellite gravity observations. Journal of Applied Geodesy, 11 (4), 231-247. 10.1515/jag-2017-0019
[Mer information]
Joud S., M., Sjöberg, L. & Bagherbandi, M. (2017). Use of GRACE Data to Detect the Present Land Uplift Rate in Fennoscandia. Geophysical Journal International, 209 (2), 909-922. 10.1093/gji/ggx063
[Mer information]
Bagherbandi, M. (2016). Deformation monitoring using different least squares adjustment methods : a simulated study. KSCE Journal of Civil Engineering, 20 (2), 855-862. 10.1007/s12205-015-0454-5
[Mer information]
Abrehdary, M., Sjöberg, L. & Bagherbandi, M. (2016). Modelling Moho depth in ocean areas based on satellite altimetry using Vening Meinesz-Moritz' method. Acta Geodaetica et Geophysica, 51 (2), 137-149. 10.1007/s40328-015-0116-6
[Mer information]
Abrehdary, M., Sjöberg, L. & Bagherbandi, M. (2016). The spherical terrain correction and its effect on the gravimetric-isostatic Moho determination. International Journal of Geophysics, 204 (1), 262-273. 10.1093/gji/ggv450
[Mer information]
Tenzer, R. & Bagherbandi, M. (2016). Theoretical deficiencies of isostatic schemes in modeling the crustal thickness along the convergent continental tectonic plate boundaries. Journal of Earth Science, 27 (6), 1045-1053. 10.1007/s12583-015-0608-x
[Mer information]
Bagherbandi, M., Sjöberg, L., Tenzer, R. & Abrehdary, M. (2015). A new Fennoscandian crustal thickness model based on CRUST1.0 and a gravimetric-isostatic approach. Earth-Science Reviews, 145, 132-145. 10.1016/j.earscirev.2015.03.003
[Mer information]
Tenzer, R., Chen, W., Tsoulis, D., Bagherbandi, M., Sjöberg, L., Novák, P. & Jin, S. (2015). Analysis of the Refined CRUST1.0 Crustal Model and its Gravity Field. Surveys in geophysics, 36 (1), 139-165. 10.1007/s10712-014-9299-6
[Mer information]
Abrehdary, M., Sjöberg, L. & Bagherbandi, M. (2015). Combined Moho parameters determination using CRUST1.0 and Vening Meinesz-Moritz model. Journal of Earth Science, 26 (4), 607-616. 10.1007/s12583-015-0571-6
[Mer information]
Tenzer, R., Bagherbandi, M. & Sjöberg, L. (2015). Comparison of various isostatic marine gravity disturbances. Journal of Earth System Science, 124 (6), 1235-1245. 10.1007/s12040-015-0610-9
[Mer information]
Tenzer, R., Bagherbandi, M., Sjöberg, L. & Novak, P. (2015). Isostatic crustal thickness under the Tibetan Plateau and Himalayas from satellite gravity gradiometry data. Earth Sciences Research Journal, 19 (2). 10.15446/esrj.v19n2.44574
[Mer information]
Sjöberg, L., Bagherbandi, M. & Tenzer, R. (2015). On Gravity Inversion by No-Topography and Rigorous Isostatic Gravity Anomalies. Pure and Applied Geophysics, 172 (10), 2669-2680. 10.1007/s00024-015-1032-y
[Mer information]
Bagherbandi, M., Tenzer, R., Sjöberg, L. & Abrehdary, M. (2015). On the residual isostatic topography effect in the gravimetric Moho determination. Journal of Geodynamics, 83, 28-36. 10.1016/j.jog.2014.11.002
[Mer information]
Bagherbandi, M., Tenzer, R. & Sjöberg, L. (2014). Moho depth uncertainties in the Vening-Meinesz Moritz inverse problem of isostasy. Studia Geophysica et Geodaetica, 58 (2), 227-248. 10.1007/s11200-013-1258-z
[Mer information]
Sjöberg, L., Abrehdry, M. & Bagherbandi, M. (2014). The observed geoid height versus Airy's and Pratt's isostatic models using matched asymptotic expansions. Acta Geodaetica et Geophysica Hungarica, 49 (4), 473-490. 10.1007/s40328-014-0064-6
[Mer information]
Sjöberg, L. & Bagherbandi, M. (2013). A study on the Fennoscandian post-glacial rebound as observed by present-day uplift rates and gravity field model GOCO02S. Acta Geodaetica et Geophysica Hungarica, 48 (3), 317-331. 10.1007/s40328-013-0025-5
[Mer information]
Bagherbandi, M. & Tenzer, R. (2013). Comparative analysis of Vening-Meinesz Moritz isostatic models using the constant and variable crust-mantle density contrast – a case study of Zealandia. Journal of Earth System Science, 122 (2), 339-348. 10.1007/s12040-013-0279-x
[Mer information]
Novák, P., Tenzer, R., Eshagh, M. & Bagherbandi, M. (2013). Evaluation of gravitational gradients generated by Earth's crustal structures. Computers & Geosciences, 51, 22-33. 10.1016/j.cageo.2012.08.006
[Mer information]
Bagherbandi, M. & Tenzer, R. (2013). Geoid-to-Quasigeoid Separation Computed Using the GRACE/GOCE Global Geopotential Model GOCO02S : A Case Study of Himalayas and Tibet. Terrestrial, Atmospheric and Oceanic Science, 24 (1), 59-68. 10.3319/TAO.2012.09.17.02(TT)
[Mer information]
Tenzer, R., Bagherbandi, M. & Vajda, P. (2013). Global model of the upper mantle lateral density structure based on combining seismic and isostatic models. Geosciences Journal, 17 (1), 65-73. 10.1007/s12303-013-0009-z
[Mer information]
Bagherbandi, M., Tenzer, R., Sjöberg, L. & Novak, P. (2013). Improved global crustal thickness modeling based on the VMM isostatic model and non-isostatic gravity correction. Journal of Geodynamics, 66, 25-37. 10.1016/j.jog.2013.01.002
[Mer information]
Bagherbandi, M. & Sjöberg, L. (2013). Improving gravimetric–isostatic models of crustal depth by correcting for non-isostatic effects and using CRUST2.0. Earth-Science Reviews, 117, 29-39. 10.1016/j.earscirev.2012.12.002
[Mer information]
Tenzer, R., Bagherbandi, M., Cheinway, H. & Chang, E. (2013). Moho Interface Modeling Beneath the Himalayas, Tibet and Central Siberia Using GOCO02S and DTM2006.0. Terrestrial, Atmospheric and Oceanic Science, 24 (4), 581-590. 10.3319/TAO.2012.11.01.02(TibXS)
[Mer information]
Tenzer, R. & Bagherbandi, M. (2013). Reference crust-mantle density contrast beneath Antarctica based on the Vening Meinesz-Moritz isostatic inverse problem and CRUST2.0 seismic model. Earth Science Research, 17 (1), 7-12.
[Mer information]
Bagherbandi, M. & Sjöberg, L. (2012). A synthetic Earth gravity model based on a topographic-isostatic model. Studia Geophysica et Geodaetica, 56 (4), 935-955. 10.1007/s11200-011-9045-1
[Mer information]
Bagherbandi, M. (2012). Combination of seismic and an isostatic crustal thickness models using Butterworth filter in a spectral approach. Journal of Asian Earth Sciences, 59, 240-248. 10.1016/j.jseaes.2012.08.008
[Mer information]
Bagherbandi, M. & Eshagh, M. (2012). Crustal thickness recovery using an isostatic model and GOCE data. Earth Planets and Space, 64 (11), 1053-1057. 10.5047/eps.2012.04.009
[Mer information]
Tenzer, R., Bagherbandi, M. & Vajda, P. (2012). Depth-dependent density change within the continental upper mantle. Slovak Academy of Sciences. Geophysical Institute. Contributions to Geophysics and Geodesy, 42 (1), 1-13. 10.2478/v10126-012-0001-z
[Mer information]
Bagherbandi, M. (2012). Global earth isostatic model using smoothed Airy-Heiskanenand Vening Meinesz hypotheses. Earth Science Informatics, 5 (2), 93-104. 10.1007/s12145-012-0099-6
[Mer information]
Bagherbandi, M. (2012). Impact of compensating mass on the topographic mass : A study using isostatic and non-isostatic Earth crustal models. Acta Geodaetica et Geophysica Hungarica, 47 (1), 29-51. 10.1556/AGeod.47.2012.1.3
[Mer information]
Bagherbandi, M. & Sjöberg, L. (2012). Modelling the density contrast and depth of the Moho discontinuity by seismic and gravimetric–isostatic methods with an application to Africa. Journal of African Earth Sciences, 68, 111-120. 10.1016/j.jafrearsci.2012.04.003
[Mer information]
Bagherbandi, M. & Sjöberg, L. (2012). Non-isostatic effects on crustal thickness : A study using CRUST2.0 in Fennoscandia. Physics of the Earth and Planetary Interiors, 200, 37-44. 10.1016/j.pepi.2012.04.001
[Mer information]
Eshagh, M. & Bagherbandi, M. (2012). Quality description for gravimetric and seismic moho models of fennoscandia through a combined adjustment. Acta Geodaetica et Geophysica Hungarica, 47 (4), 388-401. 10.1556/AGeod.47.2012.4.2
[Mer information]
Bagherbandi, M. & Eshagh, M. (2012). Recovery of Moho’s undulations based on the Vening Meinesz–Moritz theory from satellite gravity gradiometry data : A simulation study. Advances in Space Research, 49 (6), 1097-1111. 10.1016/j.asr.2011.12.033
[Mer information]
Tenzer, R. & Bagherbandi, M. (2012). Reformulation of the Vening-Meinesz Moritz Inverse Problem of Isostasy for Isostatic Gravity Disturbances. International Journal of Geosciences, 3 (5A), 918-929. 10.4236/ijg.2012.325094
[Mer information]
Tenzer, R., Bagherbandi, M. & Gladkikh, V. (2012). Signature of the upper mantle density structure in the refined gravity data. Computational Geosciences, 16 (4), 975-986. 10.1007/s10596-012-9298-y
[Mer information]
Övriga artiklar (populärvetenskap, debatt etc.)
Bagherbandi, M. & Eshagh, M. (2014). Combined Moho Estimators. Geodynamics : Research International Bulletin, 1 (3), 1-11.
Länk
[Mer information]
Böcker
Sjöberg, L. & Bagherbandi, M. (2017). Gravity Inversion and Integration : Theory and Applications in Geodesy and Geophysics. Cham: Springer Publishing Company. xiv, 383 s. 10.1007/978-3-319-50298-4
[Mer information]
Kapitel i böcker
Sjöberg, L. & Bagherbandi, M. (2016). Isostasy - Geodesy. Encyclopedia of Geodesy. Springer. 10.1007/978-3-319-02370-0_111-1
[Mer information]
Konferensbidrag
Amin, H., Sjöberg, L. & Bagherbandi, M. (2020). A global vertical datum defined by the conventional geoid potentialand the Earth ellipsoid parameters. .
Länk
[Mer information]
Jouybari, A., Bagherbandi, M. & Nilfouroushan, F. (2020). Assessment of Different GNSS and IMU Observation Weights on Photogrammetry Aerial Triangulation. . Amsterdam: FIG.
Länk
[Mer information]
Bagherbandi, M. & Gido, N. (2020). How isostasy explains continental rifting in East Africa?. .
Länk
[Mer information]
Gido, N., Amin, H., Bagherbandi, M. & Nilfouroushan, F. (2020). Satellite monitoring of mass changes and ground subsidence in Sudan’s oil fields using GRACE and Sentinel-1 data. .
Länk
[Mer information]
Amin, H., Bagherbandi, M. & Sjöberg, L. (2019). Evaluation of the Closure of Global Mean Sea Level Rise Budget over January 2005 to August 2016. .
Länk
[Mer information]
Bagherbandi, M., Gido, N., Sjöberg, L. & Tenzer, R. (2019). Studying permafrost using GRACE and in situ data in the northern high-latitudes regions. .
[Mer information]
Shafiei, M., Bagherbandi, M. & Sjöberg, L. (2018). A satellite-based gravimetric approach to GIA modelling. .
[Mer information]
Tenzer, R., Foroughi, I., Sjöberg, L., Bagherbandi, M., Hirt, C. & Pitoňák, M. (2018). Theoretical and practical aspects of defining the heights for planets and moons. .
[Mer information]
Bagherbandi, M., Sjöberg, L. & Amin, H. (2018). Towards a world vertical datum defined by the geoid potential and Earth’s ellipsoidal parameters. .
[Mer information]
Nilfouroushan, F., Bagherbandi, M. & Gido, N. (2017). Ground Subsidence And Groundwater Depletion In Iran: Integrated approach Using InSAR and Satellite Gravimetry. .
[Mer information]
Bagherbandi, M. & Tenzer, R. (2016). Comparative study of the uniform and variable Moho density contrast in the Vening Meinesz-Moritz’s isostatic scheme for the gravimetric Moho recovery. International Association of Geodesy Symposia : 3rd International Gravity Field Service, IGFS 2014; Shanghai; China; 30 June 2014 through 6 July 2014: Springer Berlin/Heidelberg. S. 199-207. 10.1007/1345_2015_210
[Mer information]
Tenzer, R. & Bagherbandi, M. (2014). Comparative Study of the Uniform and Variable Moho Density Contrast in the Vening Meinesz-Moritz’s Isostatic Scheme for the Gravimetric Moho Recovery. IGFS 2014, Proceedings of the 3rd International Gravity Field Service (IGFS), Shanghai, China, 30 June - 6 July 2014: Springer. S. 199-207. 10.1007/978-3-319-39820-4
[Mer information]
Högskolan i Gävle
www.hig.se
Box 801 76 GÄVLE
026-64 85 00 (växel)
www.hig.se
Box 801 76 GÄVLE
026-64 85 00 (växel)