Zobrazeno 1 - 10
of 39
pro vyhledávání: '"F. Diotri"'
Publikováno v:
The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XLIII-B2-2022, Pp 665-672 (2022)
Though with a less dramatic growth compared to photogrammetry, remote sensing from multispectral imagery taken by UAV (Unmanned Aerial Vehicles) platforms is applied to vegetation health monitoring, crop management, water quality assessments, geologi
Externí odkaz:
https://doaj.org/article/7e2823537afe415ea67afc8c96583d80
Publikováno v:
The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XLIII-B2-2021, Pp 53-60 (2021)
A dome-shape deformation has been found to affect the photogrammetric surface reconstruction in several real and simulated experiments. Its origin has been recognised in inaccurate estimation of the camera parameters and many papers already concentra
Externí odkaz:
https://doaj.org/article/75df7e81f7d1485dae6db105c57a5a39
Publikováno v:
The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XLIII-B2-2020, Pp 1033-1040 (2020)
Photogrammetry is becoming a widely used technique for slope monitoring and rock fall data collection. Its scalability, simplicity of components and low costs for hardware and operations makes its use constantly increasing for both civil and mining a
Externí odkaz:
https://doaj.org/article/860351a1bb294ea5a28c5a1786f18fc1
Publikováno v:
The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XLIII-B2-2020, Pp 9-16 (2020)
Unmanned Aerial Vehicles (UAV) are established platforms for photogrammetric surveys in remote areas. They are lightweight, easy to operate and can allow access to remote sites otherwise difficult (or impossible) to be surveyed with other techniques.
Externí odkaz:
https://doaj.org/article/65826ad8e7384977801523a9feb18c39
Autor:
N. Bruno, E. Coïsson, F. Diotri, L. Ferrari, S. Mikolajewska, U. Morra di Cella, R. Roncella, A. Zerbi
Publikováno v:
The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XLII-2-W11, Pp 317-323 (2019)
In this paper, an integrated analysis of the geometric and photogrammetric surveys on a 19th century bridge is proposed as an instrument for the comprehension of the historical evolution of its structural disorders, of its present conservation status
Externí odkaz:
https://doaj.org/article/b88d3c2e7f0c48cd83eba754f41e6f4c
Publikováno v:
The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XLII-2, Pp 1015-1022 (2018)
Rockfalls and rockslides represent a significant risk to human lives and infrastructures because of the high levels of energy involved in the phenomena. Generally, these events occur in accordance to specific environmental conditions, such as tempera
Externí odkaz:
https://doaj.org/article/74fa15d556ed43238aa448fc9dfe6068
Autor:
E. Dall’Asta, R. Delaloye, F. Diotri, G. Forlani, M. Fornari, U. Morra di Cella, P. Pogliotti, R. Roncella, M. Santise
Publikováno v:
The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XL-3/W3, Pp 391-397 (2015)
Photogrammetry has been used since long time to periodically control the evolution of landslides, either from aerial images as well as from ground. Landslides control and monitoring systems face a large variety of cases and situations: in hardly acce
Externí odkaz:
https://doaj.org/article/6139224e5fb24c4ab1e4ca9610162391
Publikováno v:
ISPRS Annals of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol II-5, Pp 297-304 (2014)
Photogrammetry has been used since long to periodically control the evolution of landslides; however, true monitoring is reserved to robotic total stations and ground based InSAR systems, capable of high frequency, high accurate 24h/day response. Thi
Externí odkaz:
https://doaj.org/article/3a664e2330e6437bbfd5c7e1262aec56
Publikováno v:
The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XLIII-B2-2020, Pp 1033-1040 (2020)
Photogrammetry is becoming a widely used technique for slope monitoring and rock fall data collection. Its scalability, simplicity of components and low costs for hardware and operations makes its use constantly increasing for both civil and mining a
Externí odkaz:
https://explore.openaire.eu/search/publication?articleId=doi_dedup___::c0d2555340ab1df6e02049b007293c04
https://www.int-arch-photogramm-remote-sens-spatial-inf-sci.net/XLIII-B2-2020/1033/2020/
https://www.int-arch-photogramm-remote-sens-spatial-inf-sci.net/XLIII-B2-2020/1033/2020/
Autor:
F. Acquaotta[21, 36], S. Agostini[2], L. Alderighi[18, 14], P. Allasia[16], G. Amori[23], V. Andreoli[26], F. Ardizzone[16], J. Arduini[8], V. Artale[4], E. Aruffo[5], I. Baneschi[2], C. Barbante[7], G. Barbato[27], S. Barbetta[14], C. Baroni[18, 2, 29], M. Bencardino[6], S. Bertotto[14, 21], P. Bonasoni[3], M. Borga[15], C. Boschi[2], L. Brocca[14], M. Brunetti[3], M. Busetto[3], C. Calfapietra[24], F. Calzolari[3], S. Camici[14], D. Canone[12], A. Carton[29, 20], L. Carturan[29, 19], C. Cassardo[26], L. Cavicchia[27], C. Cerrato[22], T. Chiti[30], L. Ciabatta[14], M. Cignetti[14], C. Corradini[14], E. Cremonese[11], A. Crespi[9], P. Cristofanelli[3], F. D'Amore[6], F. Dallo[7], A. Dell'Aquila[4], A. di Sarra[4], P. Di Carlo[5], G. Di Vincenzo[2], A. Dini[2], F. Diotri[11], D. Dolia[35], M. Doveri[2], S. Ferraris[12], G. Filippa[11], S. Fratianni[21, S. Gabellani[35], J. Gabrieli[7], S. Gennaro[18], S. Giamberini[2], M. Giardino[29, D. Giordan[14], D. Gisolo[12], O. Gavrichkova[24], S. Gualdi[27], H. Huwald[13], A. Irace[2], M. Isabellon[11], T. C. Landi[3], A. Langone[10], M. Laurenzi[2], S. Laviola[3], M. Lelli[2], V. Levizzani[3], M. Magnani[25, 26], M. Maione[8], V. Manara[3], M. Manunta[17], L. Marchi[37], A. Marinoni[3], G. Masetti[2], M. Mattioni[24], M. Mazzola[3], M. Maugeri[3, D. Meloni[4], M. Menichini[2], P. Mercogliano[27], M. Montesarchio[27], T. Moramarco[14], U. Morra di Cella[11], P. Mosca[25], M. C. Moscatelli[30], L. Naitza[3], B. Nisi[2], G. Pace[4], E. Palazzi[1], M. Pennisi[2], L. Perotti[29, G. Persia[1, 18], S. Piacentino[4], G. Piazzi[35], R. Pini[31], N. Pirrone[6], P. Pogliotti[11], G. Pretto[24, 32], M. Previati[12], A. Provenzale[2], D. Putero[3], B. Raco[2], M. Raffa[27], A. Reder[27], F. Roccato[3], M.C. Salvatore[18, A. Scartazza[34], E. Scoccimarro[28], D. Sferlazzo[4], F. Sprovieri[6], S. Terzago[1], P. Trisolino[3], E. Trumpy[2], M. Vardè[7], J. von Hardenberg[1], R. Viterbi[22, M. Zampieri[27, 37], A. Zanetti[10], T. Zanoner[29, M. Zorzi[18
Publikováno v:
Pisa: CNR-IGG Area della Ricerca di Pisa, 2020
info:cnr-pdr/source/autori:F. Acquaotta[21,36], S. Agostini[2], L. Alderighi[18,14], P. Allasia[16], G. Amori[23], V. Andreoli[26], F. Ardizzone[16], J. Arduini[8], V. Artale[4], E. Aruffo[5], I. Baneschi[2], C. Barbante[7], G. Barbato[27], S. Barbetta[14], C. Baroni[18,2,29], M. Bencardino[6], S. Bertotto[14,21], P. Bonasoni[3], M. Borga[15], C. Boschi[2], L. Brocca[14], M. Brunetti[3], M. Busetto[3], C. Calfapietra[24], F. Calzolari[3], S. Camici[14], D. Canone[12], A. Carton[29,20], L. Carturan[29,19], C. Cassardo[26], L. Cavicchia[27], C. Cerrato[22], T. Chiti[30], L. Ciabatta[14], M. Cignetti[14], C. Corradini[14], E. Cremonese[11], A. Crespi[9], P. Cristofanelli[3], F. D'Amore[6], F. Dallo[7], A. Dell'Aquila[4], A. di Sarra[4], P. Di Carlo[5], G. Di Vincenzo[2], A. Dini[2], F. Diotri[11], D. Dolia[35], M. Doveri[2], S. Ferraris[12], G. Filippa[11], S. Fratianni[21,36], S. Gabellani[35], J. Gabrieli[7], S. Gennaro[18], S. Giamberini[2], M. Giardino[29,21], D. Giordan[14], D. Gisolo[12], O. Gavrichkova[24], S. Gualdi[27], H. Huwald[13], A. Irace[2], M. Isabellon[11], T. C. Landi[3], A. Langone[10], M. Laurenzi[2], S. Laviola[3], M. Lelli[2], V. Levizzani[3], M. Magnani[25,26], M. Maione[8], V. Manara[3], M. Manunta[17], L. Marchi[37], A. Marinoni[3], G. Masetti[2], M. Mattioni[24], M. Mazzola[3], M. Maugeri[3,9], D. Meloni[4], M. Menichini[2], P. Mercogliano[27], M. Montesarchio[27], T. Moramarco[14], U. Morra di Cella[11], P. Mosca[25], M. C. Moscatelli[30], L. Naitza[3], B. Nisi[2], G. Pace[4], E. Palazzi[1], M. Pennisi[2], L. Perotti[29,21], G. Persia[1,18], S. Piacentino[4], G. Piazzi[35], R. Pini[31], N. Pirrone[6], P. Pogliotti[11], G. Pretto[24,32], M. Previati[12], A. Provenzale[2], D. Putero[3], B. Raco[2], M. Raffa[27], A. Reder[27], F. Roccato[3], M.C. Salvatore[18,2,29], A. Scartazza[34], E. Scoccimarro[28], D. Sferlazzo[4], F. Sprovieri[6], S. Terzago[1], P. Trisolino[3], E. Trumpy[2], M. Vardè[7], J. von Hardenberg[1], R. Viterbi[22,2], M. Zampieri[27,37], A. Zanetti[10], T. Zanoner[29,14,20], M. Zorzi[18,29]/titolo:Climate and environmental changes in Italian mountains/editore: /anno:2020
info:cnr-pdr/source/autori:F. Acquaotta[21,36], S. Agostini[2], L. Alderighi[18,14], P. Allasia[16], G. Amori[23], V. Andreoli[26], F. Ardizzone[16], J. Arduini[8], V. Artale[4], E. Aruffo[5], I. Baneschi[2], C. Barbante[7], G. Barbato[27], S. Barbetta[14], C. Baroni[18,2,29], M. Bencardino[6], S. Bertotto[14,21], P. Bonasoni[3], M. Borga[15], C. Boschi[2], L. Brocca[14], M. Brunetti[3], M. Busetto[3], C. Calfapietra[24], F. Calzolari[3], S. Camici[14], D. Canone[12], A. Carton[29,20], L. Carturan[29,19], C. Cassardo[26], L. Cavicchia[27], C. Cerrato[22], T. Chiti[30], L. Ciabatta[14], M. Cignetti[14], C. Corradini[14], E. Cremonese[11], A. Crespi[9], P. Cristofanelli[3], F. D'Amore[6], F. Dallo[7], A. Dell'Aquila[4], A. di Sarra[4], P. Di Carlo[5], G. Di Vincenzo[2], A. Dini[2], F. Diotri[11], D. Dolia[35], M. Doveri[2], S. Ferraris[12], G. Filippa[11], S. Fratianni[21,36], S. Gabellani[35], J. Gabrieli[7], S. Gennaro[18], S. Giamberini[2], M. Giardino[29,21], D. Giordan[14], D. Gisolo[12], O. Gavrichkova[24], S. Gualdi[27], H. Huwald[13], A. Irace[2], M. Isabellon[11], T. C. Landi[3], A. Langone[10], M. Laurenzi[2], S. Laviola[3], M. Lelli[2], V. Levizzani[3], M. Magnani[25,26], M. Maione[8], V. Manara[3], M. Manunta[17], L. Marchi[37], A. Marinoni[3], G. Masetti[2], M. Mattioni[24], M. Mazzola[3], M. Maugeri[3,9], D. Meloni[4], M. Menichini[2], P. Mercogliano[27], M. Montesarchio[27], T. Moramarco[14], U. Morra di Cella[11], P. Mosca[25], M. C. Moscatelli[30], L. Naitza[3], B. Nisi[2], G. Pace[4], E. Palazzi[1], M. Pennisi[2], L. Perotti[29,21], G. Persia[1,18], S. Piacentino[4], G. Piazzi[35], R. Pini[31], N. Pirrone[6], P. Pogliotti[11], G. Pretto[24,32], M. Previati[12], A. Provenzale[2], D. Putero[3], B. Raco[2], M. Raffa[27], A. Reder[27], F. Roccato[3], M.C. Salvatore[18,2,29], A. Scartazza[34], E. Scoccimarro[28], D. Sferlazzo[4], F. Sprovieri[6], S. Terzago[1], P. Trisolino[3], E. Trumpy[2], M. Vardè[7], J. von Hardenberg[1], R. Viterbi[22,2], M. Zampieri[27,37], A. Zanetti[10], T. Zanoner[29,14,20], M. Zorzi[18,29]/titolo:Climate and environmental changes in Italian mountains/editore: /anno:2020
The NextData project (2012-2018) provided quantitative information on the current state and on past, present and future climate and environmental changes in Italian mountains. The multidisciplinary approach combined field monitoring, satellite observ
Externí odkaz:
https://explore.openaire.eu/search/publication?articleId=cnr_________::cc2e746e787976482251f36e9c3368db
https://publications.cnr.it/doc/467288
https://publications.cnr.it/doc/467288