[3DF Zephyr (2020). 3DF Zephyr – photogrammetry software – 3d models from photos. Retrieved from https://www.3dflow.net/3df-zephyr-pro-3d-models-from-photos/ (date of access: 2020/06/09).]Search in Google Scholar
[3DF Zephyr Free (2020). 3DF Zephyr Free – a complete and free photogrammetry software. Retrieved from https://www.3dflow.net/3df-zephyr-free/ (date of access: 2020/06/09).]Search in Google Scholar
[Acrobat (2020). Dodawanie modeli 3D do plików PDF (Acrobat Pro). Retrieved from https://helpx.adobe.com/pl/acrobat/using/adding-3d-models-pdfs-acrobat.html (date of access: 2020/06/09).]Search in Google Scholar
[Agisoft (2020). Agisoft Metashape. Retrieved from https://www.agisoft.com/ (date of access: 2020/06/08).]Search in Google Scholar
[Agisoft (2020). Capturing photos. In Agisoft PhotoScan User Manual (pp. 8–11). Agisoft LLC. Retrieved from http://www.agisoft.com/pdf/photoscanpro_1_4_en.pdf (date of access: 2018/03/01).]Search in Google Scholar
[AliceVision (2020). Meshroom – 3D Reconstruction Software. Retrieved from https://alicevision.org/#meshroom (date of access: 2020/06/07).]Search in Google Scholar
[ArcheOS (2017). ArcheOS. Retrieved from https://www.archeos.eu/archeos/ (date of access: 2020/06/09).]Search in Google Scholar
[Bundler (2020). Bundler – Structure from Motion (SfM) for Unordered Image Collections. Retrieved from http://www.cs.cornell.edu/~snavely/bundler/ (date of access: 2020/06/07).]Search in Google Scholar
[Changchang Wu (2020). VisualSFM: A Visual Structure from Motion System. Retrieved from http://ccwu.me/vsfm/ (date of access: 2020/06/08).]Search in Google Scholar
[CloudCompare (2020). CloudCompare – Open Source project. Retrieved from https://www.danielgm.net/cc/ (date of access: 2020/06/06).]Search in Google Scholar
[ContextCapture (2020). ContextCapture, 3D Reality Modeling Software, Bentley. Retrieved from https://www.bentley.com/en/products/brands/contextcapture (date of access: 2020/06/08).]Search in Google Scholar
[CUDA (2017). CUDA Zone. Retrieved from https://developer.nvidia.com/cuda-zone (date of access: 2020/06/09).]Search in Google Scholar
[Karnicki, R. (2018). Przestrzenne odwzorowania fotogrametryczne w badaniach architektonicznych. In E. Łużyniecka (Eds.), Dziedzictwo architektoniczne: badania podstawowe i ich dokumentowanie (pp. 107–117). Wrocław: Oficyna Wydawnicza Politechniki Wrocławskiej. Retrieved from http://www.oficyna.pwr.edu.pl/ksiazki/dziedzictwo-architektoniczne-badaniapodstawowe-i-ich-dokumentowanie/ (date of access: 2019/10/12).]Search in Google Scholar
[Karnicki, R. (2019). Porównanie dostępnych systemów rekonstrukcji fotogrametrycznej bliskiego zasięgu pod kątem ich efektywności w konserwatorskim dokumentowaniu obiektów architektonicznych. In A. Legendziewicz (Eds.), Dokumentowanie i badanie architektury historycznej i ogrodów krajobrazowych. Cz. 1–2. Raporty Wydziału Architektury Politechniki Wrocławskiej. Wrocław.]Search in Google Scholar
[Klingner, B., Martin, D. and Roseborough, J. (2013). Street View Motion-from-Structure-from-Motion. In 2013 IEEE International Conference on Computer Vision. 2013 IEEE International Conference on Computer Vision (pp. 953–960). Retrieved from https://static.googleusercontent.com/media/research.google.com/pl//pubs/archive/41413.pdf (date of access: 2020/12/30).]Search in Google Scholar
[Locher, A. et al. (2016). Mobile phone and cloud — A dream team for 3D reconstruction. In 2016 IEEE Winter Conference on Applications of Computer Vision (WACV). 2016 IEEE Winter Conference on Applications of Computer Vision (WACV) (pp. 1–8). Retrieved from http://varcity.eu/paper/wacv2016_locher_dreamteam.pdf (date of access: 2019/11/20).]Search in Google Scholar
[Łuniewicz, Z. (2017). Badania nowożytnych hełmów wieżowych – obserwacje i pomiary przy użyciu techniki fotogrametrii cyfrowej wybranych obiektów z obszaru Śląska. Wrocław: Politechnika Wrocławska.]Search in Google Scholar
[Małachowicz, M. et al. (2017). Wyniki badań architektonicznych reliktów kościoła św. Stanisława w Głogowie. Wrocław: Autorska Pracownia arch. Macieja Małachowicza.]Search in Google Scholar
[Małachowicz, M., Karnicki, R. (2010). Wyniki badań architektonicznych zamku w Kruszwicy. Wrocław: Autorska Pracownia arch. Macieja Małachowicza.]Search in Google Scholar
[Mozilla (2020). Mozilla Public License Version 2.0. Retrieved from https://github.com/alicevision/meshroom (date of access: 2020/06/09).]Search in Google Scholar
[OpenCL (2013). OpenCL – The Open Standard for Parallel Programming of Heterogeneous Systems. Retrieved from https://www.khronos.org// (date of access: 09/06/20).]Search in Google Scholar
[OpenMVG (2020). OpenMVG (open Multiple View Geometry. Retrieved from https://github.com/openMVG/openMVG (date of access: 2020/06/09).]Search in Google Scholar
[Rahaman, H. and Champion, E. (2019). To 3D or Not 3D: Choosing a Photogrammetry Workflow for Cultural Heritage Groups. Heritage, 2(3), 1835–1851.10.3390/heritage2030112]Search in Google Scholar
[RealityCapture (2020). RealityCapture: Mapping and 3D Modeling Photogrammetry Software – CapturingReality.com. Retrieved from https://www.capturingreality.com/Home (date of access: 2020/06/09).]Search in Google Scholar
[ReCap (2020). ReCap Pro | Reality Capture & 3D Scanning Software | Autodesk. Retrieved from https://www.autodesk.com/products/recap/overview (date of access: 2020/06/09).]Search in Google Scholar
[Snavely, N., Seitz, S.M. and Szeliski, R. (2006). Photo tourism: Exploring photo collections in 3D. In SIGGRAPH Conference Proceedings (pp. 835–846). New York: ACM Press.]Search in Google Scholar
[Wu, C. (2013). Towards Linear-Time Incremental Structure from Motion. In 2013 International Conference on 3D Vision – 3DV 2013. 2013 International Conference on 3D Vision – 3DV 2013 (pp. 127–134).10.1109/3DV.2013.25]Search in Google Scholar