Data underlying the publication: Theoretical Minimum Uncertainty of Single-Molecule Localizations Using a Single-Photon Avalanche Diode Array
doi:10.4121/14975013.v2
The doi above is for this specific version of this dataset, which is currently the latest. Newer versions may be published in the future.
For a link that will always point to the latest version, please use
doi: 10.4121/14975013
doi: 10.4121/14975013
Datacite citation style:
Quint Houwink; Kalisvaart, Dylan; Shih-te Hung; jelmer Cnossen; Daniel fan et. al. (2021): Data underlying the publication: Theoretical Minimum Uncertainty of Single-Molecule Localizations Using a Single-Photon Avalanche Diode Array. Version 2. 4TU.ResearchData. dataset. https://doi.org/10.4121/14975013.v2
Other citation styles (APA, Harvard, MLA, Vancouver, Chicago, IEEE) available at Datacite
Dataset
choose version:
version 2 - 2021-10-21 (latest)
version 1 - 2021-10-20
CC0by
Quint Houwink
,
Dylan Kalisvaart
,
Shih-te Hung
,
jelmer Cnossen
,
Daniel fan
,
Paul Mos
,
Arin Can Ulku
,
Edoardo Charbon
,
Carlas Smith
,
Carlas Smith
The objective of this research was to find the theoretical minimum uncertainty for single-molecule localizations using a single-photon avalanche diode (SPAD). The key questions here was whether or not the binary output of a SPAD impacts the theoretical minimum uncertainty for the SPAD image model, or whether it is identical to the previously derived theoretical minimum uncertainty for an image model using Poissonian photon statistics.
After having theoretically derived this minimum uncertainty and having verified this result using simulation data we concluded that the difference between the Poissonian and binary image model is largest when saturation occurs in the pixels. To test this we had to create saturation in an experimental setup.
To do this we have built a TIRF setup where we observed DNA-PAINT nanorulers using a SwissSPAD2. Using this setup we acquired one large dataset taken at the minimum possible exposure time of the SwissSPAD2: 10 us. We then used this dataset to aggregate multiple frames into a single image, thereby setting any pixel value above 1 to 1, hereby creating saturation.
The .tiff data in this data set shows images for 8 different numbers of aggregated frames, from 16 aggregated frames to 2048 aggregated frames.
The two zipped directories contain emitter location data that is obtained when applying a localization pipeline on the .tiff files. Using the files in these directories allow for immediate reproduction of the plots in the paper.
After having theoretically derived this minimum uncertainty and having verified this result using simulation data we concluded that the difference between the Poissonian and binary image model is largest when saturation occurs in the pixels. To test this we had to create saturation in an experimental setup.
To do this we have built a TIRF setup where we observed DNA-PAINT nanorulers using a SwissSPAD2. Using this setup we acquired one large dataset taken at the minimum possible exposure time of the SwissSPAD2: 10 us. We then used this dataset to aggregate multiple frames into a single image, thereby setting any pixel value above 1 to 1, hereby creating saturation.
The .tiff data in this data set shows images for 8 different numbers of aggregated frames, from 16 aggregated frames to 2048 aggregated frames.
The two zipped directories contain emitter location data that is obtained when applying a localization pipeline on the .tiff files. Using the files in these directories allow for immediate reproduction of the plots in the paper.
history
- 2021-10-20 first online
- 2021-10-21 published, posted
publisher
4TU.ResearchData
format
.tif
associated peer-reviewed publication
Theoretical Minimum Uncertainty of Single-Molecule Localizations Using a Single-Photon Avalanche Diode Array
organizations
TU Delft, Faculty Mechanical, Maritime and Materials Engineering (3mE). Ecole Polytechnique Fédérale de Lausanne, EPFL, Advanced Quantum Architecture Lab
DATA
files (11)
- 1,236 bytesMD5:
0d0f1544e10d8d8cadc107b8bf863942data_readme.txt - 182,003,300 bytesMD5:
3f6e8d2458256872cfa6bc40cf8eda20data_experiment.zip - 1,283,225,900 bytesMD5:
e065e7dbd9b778a7c60722df726f0a9bdata_raw1_N1024.tif - 1,283,225,900 bytesMD5:
5647e895bac046f2805f83c2cfc5f5a4data_raw1_N128.tif - 1,283,225,900 bytesMD5:
3c3b88aceb24e291cfd74056fa6aa476data_raw1_N16.tif - 1,283,225,900 bytesMD5:
257f74f3d2654ed7b7458d55f44c3fa4data_raw1_N2048.tif - 1,283,225,900 bytesMD5:
3561156967f85ae1b3c94b67aceccfa4data_raw1_N256.tif - 1,283,225,900 bytesMD5:
e6d4a1041450ca33d48ac0172627af07data_raw1_N32.tif - 1,283,225,900 bytesMD5:
31b5a0595595aa2d1278bca165a00c5adata_raw1_N512.tif - 1,283,225,900 bytesMD5:
b1de21e038f77887ec7647dcc25bb966data_raw1_N64.tif - 2,807,881 bytesMD5:
71e98c19879fe650b516d9ec1f4cf5cddata_simulation.zip -
download all files (zip)
10,450,619,617 bytes unzipped
