This project sets out to design and construct a novel super-resolution technique for biological imaging: enhanced multi-focal structured illumination microscopy; merging the fields of structured-illumination and point-spread function engineering. Computer simulations demonstrate the theoretical potential of this technique and suggest at least 1.4 times increase over existing structured illumination methods. Building on this, new pattern projection techniques based on holography are developed to project the required illumination patterns over an extended field of view. In addition, new techniques based on graphical processor unit programming are developed for the post-processing and reconstruction of multi-focal structured illumination data. Finally, these techniques are tested in the imaging of a range of biological structures in both living and fixed cells. While the holographic projection and post-processing techniques proved successful, the gains achieved with enhanced multi-focal structured illumination microscopy were limited. While there is a measured gain in resolution – and a potential improvement in depth sectioning – these advantages are not apparent on all structures. Finally, the relative merits of the techniques over existing methods are discussed and potential future directions are suggested

WARD, EDWARD,NICHOLAS

English

Cilj rada bio je utvrditi razinu proizvodnje kod koje su pokriveni ukupni troškovi i
 ekonomsku efikasnost različitih sustava uzgoja rajčice (uzgoj na otvorenom, uzgoj u
 zastićenim prostorima, hidroponski uzgoj). Na temelju tehnoloških i ekonomskih polazišta
 izrañene su modelne kalkulacije pokrića varijabilnih troškova različitih sustava uzgoja rajčice.
 Modelnim kalkulacijama utvrñeni troškovi i prihodi predstavljali su podlogu za analizu točke
 pokrića i izračunavanje relevantnih ekonomskih veličina i pokazatelja različitih sustava
 uzgoja rajčice. Kod uzgoja rajčice na otvorenom potrebno je ostvariti 22,94%, kod uzgoja u u
 zaštićenom prostoru 23,05%, a kod hidroponskog uzgoja 16,89% ukupne količine proizvodnje
 za izlazak iz zone gubitka. Pozitivan financijski rezultat i vrijednosti ekonomskih pokazatelja
 proizvodnosti rada, ekonomičnosti i rentabilnosti proizvodnje pokazuju da su sustavi uzgoja
 rajčice na otvorenom, u zaštićenim prostorima s tlom i bez tla (hidroponski uzgoj) pod
 tehnološkim i ekonomskim pretpostavkama modela efikasn

Vojnović, Boris

Polytechnic "Marko Marulic” in Knin

MODELNA KALKULACIJA I ANALIZA TOČKE POKRIĆA RAZLIČITIH SUSTAVA UZGOJA RAJČICE

Durham e-Theses

Durham E-ThesesDevelopment of enhanced multi-spot structuredillumination microscopy with ﬂuorescence diﬀerenceWARD, EDWARD,NICHOLASHow to cite:WARD, EDWARD,NICHOLAS (2019) Development of enhanced multi-spot structured illuminationmicroscopy with ﬂuorescence diﬀerence, Durham theses, Durham University. Available at DurhamE-Theses Online: http://etheses.dur.ac.uk/13233/Use policyThe full-text may be used and/or reproduced, and given to third parties in any format or medium, without prior permission orcharge, for personal research or study, educational, or not-for-proﬁt purposes provided that:• a full bibliographic reference is made to the original source• a link is made to the metadata record in Durham E-Theses• the full-text is not changed in any wayThe full-text must not be sold in any format or medium without the formal permission of the copyright holders.Please consult the full Durham E-Theses policy for further details.Academic Support Oﬃce, Durham University, University Oﬃce, Old Elvet, Durham DH1 3HPe-mail: e-theses.admin@dur.ac.uk Tel: +44 0191 334 6107http://etheses.dur.ac.uk21. Programming  Background and system requirements.  Throughout the project coding was performed in MATLAB 2017a and 2018b and has been tested in both environments. The code was run on a 64-bit system with an intel i7-7700 processor and 16GB of random access memory. The graphical processor unit used was a Nvidia GTX 1050Ti or GTX 1060. Hardware control was achieved using LabVIEW 2016 with the IMAQ, IMAQdx and DAQmx packages. Detailed below is the pseudocode for the reconstruction and image processing steps respectively.  Local maxima pseudocode  The local maxima were found as follows: >>> % To remove high frequency noise, the image is convolved >>> % with the detection PSF. >>> % The convolution is performed as an element-wise multiplication >>> % in frequency space. A threshold is then subtracted to ensure only peaks >>> % above a certain intensity are found. >>> OTF = Fourier transform PSF >>> FOR each frame >>>  FT = Fourier transform pattern frame; >>>  FD = FT * OTF; >>>  Filtered = inverse Fourier transform of FD; >>>  Filtered = Filtered – threshold; >>> % Negative values are then removed. >>>  Filtered (Filtered<0) = 0; >>> % The image is then binarised, i.e. all image values > threshold >>> % are set to 1 and all others to 0. >>>  Filtered (Filtered>0) = 1; >>> % The image is then eroded. This takes clusters of positive pixels and >>> % converts them to a single positive pixel at the middle of the cluster. >>>  Eroded = erode filtered image; >>> % The coordinates of the excitation PSFs are then extracted as the  >>> % locations of all the non-zero elements of the eroded image. >>>  Coordinates = find non-zero elements of Eroded; >>> END Joint Richardson Lucy pseudocode  The workflow for JRL is outlined below:   >>> FOR the number of iterations >>>  FOR each frame >>> % The update step is calculated through a single temporary variable. >>> % The first three steps generate an expected diffraction limited image. >>>  temp = pattern frame * estimated structure; >>>  temp = Fourier transform of temp; >>>  temp = inverse Fourier transform of temp * detection OTF; >>> % This is then compared to the raw data incorporating Gaussian noise >>> % with a variance, sigma, into the reconstruction. >>>  temp = (raw data frame + sigma) / (temp + sigma); >>> % This is then convolved with the detection PSF. >>>  temp = Fourier transform of temp; >>>  temp = inverse Fourier transform of temp * detection OTF; >>> % The update is then formed form the pattern and temp. This is updated >>> % for each frame and then applied after all frames have been processed. >>>  temp = temp * pattern; >>>  update = update + temp; >>>  END >>> estimate = estimate * update; >>>  END >>>  %While holding the information in a constantly changing temporary variable is a  >>>  %convoluted approach, it accelerates performance as the multiple cores are not  >>> %attempting to access the same memory location simultaneously.    Pattern Illuminated Fourier Ptychography pseudocode  The workflow for PIFP is outlined below:   >>> % As the Fourier Transform of the patterns is used throughout and remains >>> % constant, this is calculated before the iterations begin >>> FD = Fourier transform of patterns >>> % Begin the PIFP iterations. >>> FOR the number of iterations >>>  FOR each frame >>> % PIFP works best if the order of pattern illuminations is shuffled so a frame and. >>> % matching pattern are chosen at random and the predicted response is calculated >>>  FR = random raw data image; >>>  PR = matching random pattern; >>>  response = estimate sample * PR; >>> % We move to the Fourier domain to perform intermediate calculations.  >>>  FT = Fourier transform of response;  >>>  FT = FT - OTF * Fourier transform of PR; >>>  FT = FT + conjugate of OTF * Fourier transform of FD; >>> % We then move to real space to calculate the update.  >>>  update = absolute value of the inverse Fourier transform of FT;  >>>   update = update – response; >>>  update = update * PR / max value of PR2; >>> % We then apply the update to the estimate.  >>>   estimate = estimate + update; >>>  END >>> END >>>  % Looking at the code, the update is applied after every frame rather than after >>> % every iteration as in JRL. In addition, the number of variables that must be  >>> % held simultaneously increases the memory usage. The combination of these  >>> % two factors means that PIFP is poorly suited to GPU acceleration.  Estimating the pattern shift  The workflow for pattern shift estimation is outlined below:  >>>   % To build the ideal pattern stack the shift of each grid relative >>>   % to the previous one is calculated. >>>  shift = pattern spacing (pixels) / number of shifts; >>>  FOR every frame >>>   next frame in stack = shifted previous frame; >>>     END >>>  % The global shift of this ideal stack over the image must then >>>  % be determined by scanning the whole ideal stack over the predicted >>>  % sample and comparing to the raw data. >>>  predicted sample = mean of all frames of the raw data; >>> FOR every x shift scanned >>>  FOR every y shift scanned >>>   FOR every frame >>>    shift the corresponding frame of the ideal pattern… >>>     … by the x and y shifts being tested;  >>>    predicted image = pattern frame * predicted sample; >>>    difference = (predicted imaged – raw data)2; >>>   END >>>               END >>>           error of this shift = sum of all differences; >>>     END >>> global shift = shift with the lowest error value; >>> apply the global shift to the ideal pattern;    Downloads:  The full code and supporting documentation can be found at: https://github.com/edward-n-ward This also includes the programs used for the holographic projection and hardware control. The relevant publications can be found at Ward et al. 2018[1] and 2019[2] for the simulations and holographic projection respectively.  2. References 1.  E. N. Ward, F. H. Torkelsen, and R. Pal, "Enhancing multi-spot structured illumination microscopy with fluorescence difference," R. Soc. Open Sci. 5(3), 171336 (2018). 2.  E. N. Ward and R. Pal, "Holographic projection for multispot structured illumination microscopy," J. Microsc. 274(2), 114–120 (2019).      

Development of enhanced multi-spot structured illumination microscopy with fluorescence difference

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Development of enhanced multi-spot structured illumination microscopy with fluorescence difference

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