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Frank Niemeyer

Co-Founder & CTO at OSORA Medical Fracture Analytics
Bavaria, Germany
http://frankniemeyer.blogspot.de
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Favorite editor: Visual Studio Code • First computer: Intel i80486 SX/25, 4 MiB RAM, 120 MB HDD
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Position Apr 2021 → Current (2 months)
Co-Founder | CTO at OSORA Medical Fracture Analytics
finite-element-analysis fuzzy-logic machine-learning python numpy .net c# blazor asp.net-core azure

Building the technical foundation for making the healing simulation accessible

Building the technical foundation for making the healing simulation accessible

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Open source Apr 2014 → Current (7 years, 2 months)

Generic pointer operations and highly efficient native 64-bit arrays for .NET languages

Project lead

Generic pointer operations and highly efficient native 64-bit arrays for .NET languages

Project lead

f# c# .net native low-level simd

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Open source Jan 2014 → Current (7 years, 5 months)

Levenberg-Marquardt for C# (and other .NET languages)

Project lead

Levenberg-Marquardt for C# (and other .NET languages)

Project lead

c# f# c mathematical-optimization interop .net

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Position 2013 → Mar 2021 (8 years, 3 months)
Research Associate (Post Doc) at University of Ulm, Institute for Orthopaedic Research and Biomechanics
scikit-learn scipy machine-learning montecarlo finite-element-analysis motion-capturing tensorflow deep-learning
  • Applied deep learning for biomedical image analysis on X-ray, MRI and CT data (landmark localization, classification, object detection, segmentation & generative models)
  • Machine-learning approaches for automatic calibration of models in high-dimensional parameter spaces
  • Sensitivity and uncertainty analysis of parameterized models
  • Applied deep learning for biomedical image analysis on X-ray, MRI and CT data (landmark localization, classification, object detection, segmentation & generative models)
  • Machine-learning approaches for automatic calibration of models in high-dimensional parameter spaces
  • Sensitivity and uncertainty analysis of parameterized models

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Blogs or videos Jul 2020
deep-learning tensorflow python

With a reliability of κ > 0.9, our system clearly outperforms average human interrater as well as intrarater reliability. With an average sensitivity of more than 90%, our classifier also surpasses state-of-the-art machine learning solutions for automatically grading disc degeneration.

With a reliability of κ > 0.9, our system clearly outperforms average human interrater as well as intrarater reliability. With an average sensitivity of more than 90%, our classifier also surpasses state-of-the-art machine learning solutions for automatically grading disc degeneration.

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Blogs or videos Jun 2018
finite-element-analysis volume-of-fluid level-set-method openfoam

We present a novel numerical model of the fracture-healing process using interface-capturing techniques, a well-known approach from fields like fluid dynamics, to describe tissue growth. One advantage of this method is its direct connection to experimentally observable parameters, including tissue-growth velocities. In our model, osteogenesis, chondrogenesis and revascularisation are triggered by mechanical stimuli via mechano-transduction based on previously established hypothesis of Claes and Heigele. After experimentally verifying the convergence of the numerical method, we compare the predictions of our model with those of the already established Ulm bone-healing model, which serves as a benchmark, and corroborate our results with existing animal experiments. We demonstrate that the new model can predict the history of the interfragmentary movement and forecast a tissue evolution that appears similar to the experimental results. Furthermore, we compare the relative tissue concentration in the healing domain with outcomes of animal experiments. Finally, we discuss the possible application of the model to new fields, where numerical simulations could also prove beneficial.

We present a novel numerical model of the fracture-healing process using interface-capturing techniques, a well-known approach from fields like fluid dynamics, to describe tissue growth. One advantage of this method is its direct connection to experimentally observable parameters, including tissue-growth velocities. In our model, osteogenesis, chondrogenesis and revascularisation are triggered by mechanical stimuli via mechano-transduction based on previously established hypothesis of Claes and Heigele. After experimentally verifying the convergence of the numerical method, we compare the predictions of our model with those of the already established Ulm bone-healing model, which serves as a benchmark, and corroborate our results with existing animal experiments. We demonstrate that the new model can predict the history of the interfragmentary movement and forecast a tissue evolution that appears similar to the experimental results. Furthermore, we compare the relative tissue concentration in the healing domain with outcomes of animal experiments. Finally, we discuss the possible application of the model to new fields, where numerical simulations could also prove beneficial.

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Blogs or videos May 2018
deep-learning machine-learning generative-adversarial-network

In silico trials recently emerged as a disruptive technology, which may reduce the costs related to the development and marketing approval of novel medical technologies, as well as shortening their time-to-market. In these trials, virtual patients are recruited from a large database and their response to the therapy, such as the implantation of a medical device, is simulated by means of numerical models. In this work, we propose the use of generative adversarial networks to produce synthetic radiological images to be used in in silico trials. The generative models produced credible synthetic sagittal X-rays of the lumbar spine based on a simple sketch, and were able to generate sagittal radiological images of the trunk using coronal projections as inputs, and vice versa. Although numerous inaccuracies in the anatomical details may still allow distinguishing synthetic and real images in the majority of cases, the present work showed that generative models are a feasible solution for creating synthetic imaging data to be used in in silico trials of novel medical devices.

In silico trials recently emerged as a disruptive technology, which may reduce the costs related to the development and marketing approval of novel medical technologies, as well as shortening their time-to-market. In these trials, virtual patients are recruited from a large database and their response to the therapy, such as the implantation of a medical device, is simulated by means of numerical models. In this work, we propose the use of generative adversarial networks to produce synthetic radiological images to be used in in silico trials. The generative models produced credible synthetic sagittal X-rays of the lumbar spine based on a simple sketch, and were able to generate sagittal radiological images of the trunk using coronal projections as inputs, and vice versa. Although numerous inaccuracies in the anatomical details may still allow distinguishing synthetic and real images in the majority of cases, the present work showed that generative models are a feasible solution for creating synthetic imaging data to be used in in silico trials of novel medical devices.

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Position 2012 → 2016 (5 years)
finite-element-analysis fuzzy-logic comsol pde computational-science mathematical-modeling numerical-methods python numpy c# .net c++
  • Development of a new spinal fusion device: mathematical modeling & simulation
  • Organ-scale bone healing simulations with microscopic resolution: Bone healing is, like many problems in biology, a multi-scale problem where the physics on different spatial as well as temporal scales affect each other. We're working on both a "semi-brute force" HPC-based solution using adaptive Space Time FEM, utilizing tier-1 and -2 HPC infrastructure, as well as more intelligent multi-scale approaches.
  • Continuous mathematical formulation for bone healing: We're trying to come up with a analytical formulation of our fuzzy-logic-based healing model (probably a system of non-linear delay integro-PDEs)
  • Development of a new spinal fusion device: mathematical modeling & simulation
  • Organ-scale bone healing simulations with microscopic resolution: Bone healing is, like many problems in biology, a multi-scale problem where the physics on different spatial as well as temporal scales affect each other. We're working on both a "semi-brute force" HPC-based solution using adaptive Space Time FEM, utilizing tier-1 and -2 HPC infrastructure, as well as more intelligent multi-scale approaches.
  • Continuous mathematical formulation for bone healing: We're trying to come up with a analytical formulation of our fuzzy-logic-based healing model (probably a system of non-linear delay integro-PDEs)

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Position 2007 → 2016 (10 years)
linux pbs sge scientific-computing scientific-software administration hpc

Administration and maintenance (software, hardware) of the UZWR’s Linux-based HPC cluster "Pacioli"

Administration and maintenance (software, hardware) of the UZWR’s Linux-based HPC cluster "Pacioli"

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-1
Top post Oct 2016

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Blogs or videos Oct 2016

TensorFlow—or rather: its build system—hasn’t yet been ported to Windows. Until then, one can get by using Docker containers or running full-blown Linux VMs. With the introduction of the WSL (Windows Subsystem for Linux) as a part of Windows 10 Anniversary Update, however, it has become possible to run the Linux-version of TensorFlow on Windows in its Ubuntu user space (CPU only, sadly). WSL is still in beta, so there are some quirks to be expected.

TensorFlow—or rather: its build system—hasn’t yet been ported to Windows. Until then, one can get by using Docker containers or running full-blown Linux VMs. With the introduction of the WSL (Windows Subsystem for Linux) as a part of Windows 10 Anniversary Update, however, it has become possible to run the Linux-version of TensorFlow on Windows in its Ubuntu user space (CPU only, sadly). WSL is still in beta, so there are some quirks to be expected.

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Blogs or videos Aug 2015

While the previous two parts where more focused on theory and concepts, we are now going to actually get our hands dirty and write some code to see how different approaches to SIMD processing compare…

While the previous two parts where more focused on theory and concepts, we are now going to actually get our hands dirty and write some code to see how different approaches to SIMD processing compare…

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Blogs or videos Jun 2015

Last time we looked at a very basic example of a data parallel problem: adding two arrays. Unfortunately, data parallelism is not always so easy to extract from existing code bases and often requires considerable effort. Today we will therefore address a slightly more complicated problem and move step by step from a pure scalar to a fully vectorized version.

Last time we looked at a very basic example of a data parallel problem: adding two arrays. Unfortunately, data parallelism is not always so easy to extract from existing code bases and often requires considerable effort. Today we will therefore address a slightly more complicated problem and move step by step from a pure scalar to a fully vectorized version.

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Blogs or videos Jul 2014

In my previous post I demonstrated how one can use the NativeIntrop library to easily implement file I/O for structured binary data formats, STL in this particular case. In this example, we used NativeInterop.Stream.ReadUnmanagedStructRange to read a sequence of bytes from a file as an array of STL triangle structs.

In my previous post I demonstrated how one can use the NativeIntrop library to easily implement file I/O for structured binary data formats, STL in this particular case. In this example, we used NativeInterop.Stream.ReadUnmanagedStructRange to read a sequence of bytes from a file as an array of STL triangle structs.

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Blogs or videos Apr 2014

Not being able to exploit today's processors SIMD processing capabilities is a major culprit when implementing high-performance (e. g. numerical) applications in C# (or any other CLI language). While there is Mono.Simd, there is no solutions for applications running on top of Microsoft's own runtime (CLR), despite popular demand ... until now!

Not being able to exploit today's processors SIMD processing capabilities is a major culprit when implementing high-performance (e. g. numerical) applications in C# (or any other CLI language). While there is Mono.Simd, there is no solutions for applications running on top of Microsoft's own runtime (CLR), despite popular demand ... until now!

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Top post Nov 2013

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Education Jan 2008 → Jul 2013
Dr. biol. hum. ("PhD" in computational biomechanics/biology), Ulm University
c# simulation finite-element-analysis fuzzy-logic hpc linux f# bash python c matlab

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Blogs or videos Jul 2013

Superficially, bone seems to be a static part of the human body. In reality, bone tissue constantly adapts itself to an ever changing mechanical environment. This work explores mathematical models approximating the complex biological processes that provide bone with its unique regenerative capabilities. We apply numerical simulations implementing these conceptual models to both classical fracture healing as well as distraction osteogenesis, a surgical procedure for stimulating bone regeneration. The predictions of the numerical simulations allow for a deep discussion of the role of mechanotransduction in bone healing in general and distraction osteogenesis in particular.

Superficially, bone seems to be a static part of the human body. In reality, bone tissue constantly adapts itself to an ever changing mechanical environment. This work explores mathematical models approximating the complex biological processes that provide bone with its unique regenerative capabilities. We apply numerical simulations implementing these conceptual models to both classical fracture healing as well as distraction osteogenesis, a surgical procedure for stimulating bone regeneration. The predictions of the numerical simulations allow for a deep discussion of the role of mechanotransduction in bone healing in general and distraction osteogenesis in particular.

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Position 2007 → 2012 (6 years)
Research Assistant at University of Ulm, Institute for Orthopaedic Research and Biomechanics
finite-element-analysis montecarlo fuzzy-logic ansys abaqus r scipy numpy matlab
  • Development of a numerical model of distraction osteogenesis and bone healing in general The model predicts the healing process (i.e. spatio-temporal tissue changes) based on the applied mechanical stimuli (computed via solid-structrual, nonlinear, transient FEA) and a set of tissue differentiation rules implemented in fuzzy logic to infer likely concentration deltas required by the time-integration procedure (initial boundary value problem).
  • Development of a fully-parameteric FE model of the human spine, supporting scoliosis treatment research Most FE models in the biomechanics field are built "bottom-up," often based on patient-specific imaging data, and are thus quite inflexible and really only useful for making patient-specific predictions. Our new "fully-parametric" model instead really is a model generator that automatically generates spine models based on a set of anatomical parameters.
  • Development of a numerical model of distraction osteogenesis and bone healing in general The model predicts the healing process (i.e. spatio-temporal tissue changes) based on the applied mechanical stimuli (computed via solid-structrual, nonlinear, transient FEA) and a set of tissue differentiation rules implemented in fuzzy logic to infer likely concentration deltas required by the time-integration procedure (initial boundary value problem).
  • Development of a fully-parameteric FE model of the human spine, supporting scoliosis treatment research Most FE models in the biomechanics field are built "bottom-up," often based on patient-specific imaging data, and are thus quite inflexible and really only useful for making patient-specific predictions. Our new "fully-parametric" model instead really is a model generator that automatically generates spine models based on a set of anatomical parameters.

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Top post Aug 2012

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Blogs or videos May 2012

Typical FE models of the human lumbar spine consider a single, fixed geometry. Such models cannot account for potential effects of the natural variability of the spine's…

Typical FE models of the human lumbar spine consider a single, fixed geometry. Such models cannot account for potential effects of the natural variability of the spine's…

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Education 2000 → 2007
Dipl.-Inf. (German equivalent to MSc in Computer Science), Ulm University
raytracing simulation graphics c# multithreading performance

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Conventional programming languages are growing ever more enormous, but not stronger. Inherent defects at the most basic level cause them to be both fat and weak: their primitive word-at-a-time style of program- ruing inherited from their common ancestor--the von Neumann computer, their close coupling of semantics to state transitions, their division of programming into a world of expressions and a world of statements, their inability to effectively use powerful combining forms for building new programs from existing ones, and their lack of useful mathematical properties for reasoning about programs.

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Frank Niemeyer

Technical Skills

Likes: functional-programming .net c# f# python scientific-computing hpc performance machine-learning computer-vision graphics gpgpu deep-learning conv-neural-network scipy low-level-code
Dislikes: ejb erp crm

Experience

Apr 2021 → Current Co-Founder | CTO OSORA Medical Fracture Analytics
finite-element-analysis, fuzzy-logic, machine-learning, python, numpy, .net, c#, blazor, asp.net-core, azure

Building the technical foundation for making the healing simulation accessible

2013 → Mar 2021 Research Associate (Post Doc) University of Ulm, Institute for Orthopaedic Research and Biomechanics
scikit-learn, scipy, machine-learning, montecarlo, finite-element-analysis, motion-capturing, tensorflow, deep-learning
  • Applied deep learning for biomedical image analysis on X-ray, MRI and CT data (landmark localization, classification, object detection, segmentation & generative models)
  • Machine-learning approaches for automatic calibration of models in high-dimensional parameter spaces
  • Sensitivity and uncertainty analysis of parameterized models
2012 → 2016 Research Associate (Post Doc) University of Ulm, Scientific Computing Centre Ulm (UZWR)
finite-element-analysis, fuzzy-logic, comsol, pde, computational-science, mathematical-modeling, numerical-methods, python, numpy, c#, .net, c++
  • Development of a new spinal fusion device: mathematical modeling & simulation
  • Organ-scale bone healing simulations with microscopic resolution: Bone healing is, like many problems in biology, a multi-scale problem where the physics on different spatial as well as temporal scales affect each other. We're working on both a "semi-brute force" HPC-based solution using adaptive Space Time FEM, utilizing tier-1 and -2 HPC infrastructure, as well as more intelligent multi-scale approaches.
  • Continuous mathematical formulation for bone healing: We're trying to come up with a analytical formulation of our fuzzy-logic-based healing model (probably a system of non-linear delay integro-PDEs)
2007 → 2016 HPC cluster administrator University of Ulm, Scientific Computing Centre Ulm (UZWR)
linux, pbs, sge, scientific-computing, scientific-software, administration, hpc

Administration and maintenance (software, hardware) of the UZWR’s Linux-based HPC cluster "Pacioli"

2007 → 2012 Research Assistant University of Ulm, Institute for Orthopaedic Research and Biomechanics
finite-element-analysis, montecarlo, fuzzy-logic, ansys, abaqus, r, scipy, numpy, matlab
  • Development of a numerical model of distraction osteogenesis and bone healing in general The model predicts the healing process (i.e. spatio-temporal tissue changes) based on the applied mechanical stimuli (computed via solid-structrual, nonlinear, transient FEA) and a set of tissue differentiation rules implemented in fuzzy logic to infer likely concentration deltas required by the time-integration procedure (initial boundary value problem).
  • Development of a fully-parameteric FE model of the human spine, supporting scoliosis treatment research Most FE models in the biomechanics field are built "bottom-up," often based on patient-specific imaging data, and are thus quite inflexible and really only useful for making patient-specific predictions. Our new "fully-parametric" model instead really is a model generator that automatically generates spine models based on a set of anatomical parameters.

Education

Jan 2008 → Jul 2013 Dr. biol. hum. ("PhD" in computational biomechanics/biology) Ulm University
c#, simulation, finite-element-analysis, fuzzy-logic, hpc, linux, f#, bash, python, c, matlab
2000 → 2007 Dipl.-Inf. (German equivalent to MSc in Computer Science) Ulm University
raytracing, simulation, graphics, c#, multithreading, performance

Projects & Interests

Apr 2009 → Current Stack Overflow https://stackoverflow.com/users/96583/frank
Written 36 answers. Active in c#, .net and f#.
Apr 2014 → Current NativeInterop https://bitbucket.org/frank_niemeyer/nativeinterop
f#, c#, .net, native, low-level, simd

Generic pointer operations and highly efficient native 64-bit arrays for .NET languages

Project lead

Jan 2014 → Current LMDotNet https://bitbucket.org/frank_niemeyer/lmdotnet
c#, f#, c, mathematical-optimization, interop, .net

Levenberg-Marquardt for C# (and other .NET languages)

Project lead

Public Artifacts

Jul 2020 A Deep Learning Model for the Accurate and Reliable Classification of Disc Degeneration Based on MRI Data https://journals.lww.com/investigativeradiology/Fulltext/2021/02000/A_Deep_Learning_Model_for_the_Accurate_and.2.aspx
deep-learning, tensorflow, python

With a reliability of κ > 0.9, our system clearly outperforms average human interrater as well as intrarater reliability. With an average sensitivity of more than 90%, our classifier also surpasses state-of-the-art machine learning solutions for automatically grading disc degeneration.

Jun 2018 Modelling the fracture-healing process as a moving-interface problem using an interface-capturing approach https://www.tandfonline.com/doi/abs/10.1080/10255842.2018.1487554
finite-element-analysis, volume-of-fluid, level-set-method, openfoam

We present a novel numerical model of the fracture-healing process using interface-capturing techniques, a well-known approach from fields like fluid dynamics, to describe tissue growth. One advantage of this method is its direct connection to experimentally observable parameters, including tissue-growth velocities. In our model, osteogenesis, chondrogenesis and revascularisation are triggered by mechanical stimuli via mechano-transduction based on previously established hypothesis of Claes and Heigele. After experimentally verifying the convergence of the numerical method, we compare the predictions of our model with those of the already established Ulm bone-healing model, which serves as a benchmark, and corroborate our results with existing animal experiments. We demonstrate that the new model can predict the history of the interfragmentary movement and forecast a tissue evolution that appears similar to the experimental results. Furthermore, we compare the relative tissue concentration in the healing domain with outcomes of animal experiments. Finally, we discuss the possible application of the model to new fields, where numerical simulations could also prove beneficial.

May 2018 Exploring the Potential of Generative Adversarial Networks for Synthesizing Radiological Images of the Spine to be Used in In Silico Trials https://www.frontiersin.org/articles/10.3389/fbioe.2018.00053/full
deep-learning, machine-learning, generative-adversarial-network

In silico trials recently emerged as a disruptive technology, which may reduce the costs related to the development and marketing approval of novel medical technologies, as well as shortening their time-to-market. In these trials, virtual patients are recruited from a large database and their response to the therapy, such as the implantation of a medical device, is simulated by means of numerical models. In this work, we propose the use of generative adversarial networks to produce synthetic radiological images to be used in in silico trials. The generative models produced credible synthetic sagittal X-rays of the lumbar spine based on a simple sketch, and were able to generate sagittal radiological images of the trunk using coronal projections as inputs, and vice versa. Although numerous inaccuracies in the anatomical details may still allow distinguishing synthetic and real images in the majority of cases, the present work showed that generative models are a feasible solution for creating synthetic imaging data to be used in in silico trials of novel medical devices.

Oct 2016 Running TensorFlow natively on Windows 10 http://frankniemeyer.blogspot.de/2016/10/running-tensorflow-natively-on-windows.html

TensorFlow—or rather: its build system—hasn’t yet been ported to Windows. Until then, one can get by using Docker containers or running full-blown Linux VMs. With the introduction of the WSL (Windows Subsystem for Linux) as a part of Windows 10 Anniversary Update, however, it has become possible to run the Linux-version of TensorFlow on Windows in its Ubuntu user space (CPU only, sadly). WSL is still in beta, so there are some quirks to be expected.

Aug 2015 Frank’s Scratchpad: SIMD Fundamentals. Part III: Implementation & Benchmarks http://frankniemeyer.blogspot.com/2015/08/simd-fundamentals-part-iii.html

While the previous two parts where more focused on theory and concepts, we are now going to actually get our hands dirty and write some code to see how different approaches to SIMD processing compare…

Jun 2015 Frank’s Scratchpad: SIMD Fundamentals. Part II: AoS, SoA, Gather/Scatter - Oh my! http://frankniemeyer.blogspot.com/2015/06/simd-fundamentals-part-ii-aos-soa.html

Last time we looked at a very basic example of a data parallel problem: adding two arrays. Unfortunately, data parallelism is not always so easy to extract from existing code bases and often requires considerable effort. Today we will therefore address a slightly more complicated problem and move step by step from a pure scalar to a fully vectorized version.

Jul 2014 Methods for Reading Structured Binary Data: Benchmarks & Comparisons http://frankniemeyer.blogspot.com/2014/07/methods-for-reading-structured-binary.html

In my previous post I demonstrated how one can use the NativeIntrop library to easily implement file I/O for structured binary data formats, STL in this particular case. In this example, we used NativeInterop.Stream.ReadUnmanagedStructRange to read a sequence of bytes from a file as an array of STL triangle structs.

Apr 2014 A first look at RyuJIT CTP3 and SIMD (SSE2) support for .NET http://frankniemeyer.blogspot.com/2014/04/a-first-look-at-ruyjit-ctp3-and-simd.html

Not being able to exploit today's processors SIMD processing capabilities is a major culprit when implementing high-performance (e. g. numerical) applications in C# (or any other CLI language). While there is Mono.Simd, there is no solutions for applications running on top of Microsoft's own runtime (CLR), despite popular demand ... until now!

Jul 2013 Simulation of fracture healing (PhD Thesis) http://dx.doi.org/10.18725/OPARU-2961

Superficially, bone seems to be a static part of the human body. In reality, bone tissue constantly adapts itself to an ever changing mechanical environment. This work explores mathematical models approximating the complex biological processes that provide bone with its unique regenerative capabilities. We apply numerical simulations implementing these conceptual models to both classical fracture healing as well as distraction osteogenesis, a surgical procedure for stimulating bone regeneration. The predictions of the numerical simulations allow for a deep discussion of the role of mechanotransduction in bone healing in general and distraction osteogenesis in particular.

May 2012 Geometry strongly influences the response of numerical models of the lumbar spine—A probabilistic finite element analysis http://www.sciencedirect.com/science/article/pii/S0021929012001431

Typical FE models of the human lumbar spine consider a single, fixed geometry. Such models cannot account for potential effects of the natural variability of the spine's…

Readings

Physically Based Rendering, Second Edition: From Theory To Implementation Matt Pharr, Greg Humphreys http://www.amazon.com/Physically-Based-Rendering-Second-Edition/dp/0123750792%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D0123750792
Programming F#: A comprehensive guide for writing simple code to solve complex problems (Animal Guide) Chris Smith http://www.amazon.com/Programming-comprehensive-writing-complex-problems/dp/0596153643%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D0596153643
Expert F# 2.0 (Expert's Voice in F#) Don Syme, Adam Granicz, Antonio Cisternino http://www.amazon.com/Expert-2-0-Experts-Voice-Syme/dp/1430224312%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D1430224312
Beginning F# Robert Pickering http://www.amazon.com/Beginning-F-Robert-Pickering/dp/1430223898%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D1430223898
Introduction to Linear Algebra, Fourth Edition Gilbert Strang http://www.amazon.com/Introduction-Linear-Algebra-Fourth-Edition/dp/0980232716%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D0980232716
Lehrbuch der Analysis 1: Mit 810 Aufgaben, zum Teil mit Losungen (German Edition) Harro Heuser http://www.amazon.com/Lehrbuch-Analysis-Aufgaben-Losungen-Edition/dp/3519622335%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D3519622335
Lehrbuch der Analysis. Teil 2 Harro Heuser http://www.amazon.com/Lehrbuch-Analysis-Teil-Harro-Heuser/dp/3519522322%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D3519522322
Computer Networks (5th Edition) Andrew S. Tanenbaum, David J. Wetherall http://www.amazon.com/Computer-Networks-Edition-Andrew-Tanenbaum/dp/0132126958%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D0132126958
Modern Operating Systems (3rd Edition) Andrew S. Tanenbaum http://www.amazon.com/Modern-Operating-Systems-3rd-Edition/dp/0136006639%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D0136006639
Grundkurs Künstliche Intelligenz: Eine praxisorientierte Einführung (Computational Intelligence) (German Edition) Wolfgang Ertel http://www.amazon.com/Grundkurs-K%C3%BCnstliche-Intelligenz-praxisorientierte-Computational/dp/3834807834%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D3834807834
C# 4.0 in a Nutshell: The Definitive Reference Joseph Albahari, Ben Albahari http://www.amazon.com/4-0-Nutshell-The-Definitive-Reference/dp/0596800959%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D0596800959
Compiler Construction (International Computer Science Series) Niklaus Wirth http://www.amazon.com/Compiler-Construction-International-Computer-Science/dp/0201403536%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D0201403536
Category Theory (Oxford Logic Guides) Steve Awodey http://www.amazon.com/Category-Theory-Oxford-Logic-Guides/dp/0199237182%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D0199237182
Mathematik (German Edition) Tilo Arens, Frank Hettlich, Christian Karpfinger, Ulrich Kockelkorn, Klaus Lichtenegger, Hellmuth Stachel http://www.amazon.com/Mathematik-German-Edition-Tilo-Arens/dp/3827423473%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D3827423473
Technische Mechanik: Band 3: Kinetik (Springer-Lehrbuch) (German Edition) Dietmar Gross, Werner Hauger, Jörg Schröder, Wolfgang A. Wall http://www.amazon.com/Technische-Mechanik-Kinetik-Springer-Lehrbuch-Edition/dp/354034084X%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D354034084X
Technische Mechanik, computerunterstützt. Statik. Festigkeitslehre. Kinematik / Kinetik. Helga Dankert, Jürgen Dankert http://www.amazon.com/Technische-Mechanik-computerunterst%C3%BCtzt-Festigkeitslehre-Kinematik/dp/3519165236%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D3519165236
An Introduction to Kolmogorov Complexity and Its Applications (Texts in Computer Science) Ming Li, Paul M.B. Vitányi http://www.amazon.com/Introduction-Kolmogorov-Complexity-Applications-Computer/dp/0387339981%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D0387339981
Head First Design Patterns Elisabeth Freeman, Eric Freeman, Bert Bates, Kathy Sierra, Elisabeth Robson http://www.amazon.com/First-Design-Patterns-Elisabeth-Freeman/dp/0596007124%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D0596007124
Borland Delphi 5. Grundlagen und Profiwissen. Walter Doberenz, Thomas Kowalski http://www.amazon.com/Borland-Delphi-5-Grundlagen-Profiwissen/dp/3446213643%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D3446213643
Turbo Pascal 7.0 (4th Edition) Walter Savitch http://www.amazon.com/Turbo-Pascal-7-0-4th-Edition/dp/0805304185%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D0805304185
Practical Common Lisp Peter Seibel http://www.amazon.com/Practical-Common-Lisp-Peter-Seibel/dp/1590592395%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D1590592395
Learn You a Haskell for Great Good!: A Beginner's Guide Miran Lipovaca http://www.amazon.com/Learn-You-Haskell-Great-Good/dp/1593272839%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D1593272839
Real World Haskell Bryan O'Sullivan, John Goerzen, Don Stewart http://www.amazon.com/Real-World-Haskell-Bryan-OSullivan/dp/0596514980%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D0596514980
Programming Clojure Stuart Halloway, Aaron Bedra http://www.amazon.com/Programming-Clojure-Stuart-Halloway/dp/1934356867%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D1934356867
Clojure Programming Chas Emerick, Brian Carper, Christophe Grand http://www.amazon.com/Clojure-Programming-Chas-Emerick/dp/1449394701%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D1449394701
Clojure in Action Amit Rathore http://www.amazon.com/Clojure-Action-Amit-Rathore/dp/1935182595%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D1935182595
Programming in Haskell Professor Graham Hutton http://www.amazon.com/Programming-Haskell-Professor-Graham-Hutton/dp/0521692695%3FSubscriptionId%3DAKIAIIBINOD46VC3JCLQ%26tag%3Dstackoverfl08-20%26linkCode%3Dxm2%26camp%3D2025%26creative%3D165953%26creativeASIN%3D0521692695
Using Lawvere theories to combine effects A Neighborhood of Infinity http://blog.sigfpe.com/2012/02/using-lawvere-theories-to-combine.html

In an

Your Mouse is a Database - ACM Queue ACMQ Site - ACM Queue http://queue.acm.org/detail.cfm?id=2169076

Web and mobile applications are increasingly composed of asynchronous and realtime streaming services and push notifications.

OCaml for the Masses - ACM Queue ACMQ Site - ACM Queue http://queue.acm.org/detail.cfm?id=2038036

Why the next language you learn should be functional

Why LINQ Matters - ACM Queue ACMQ Site - ACM Queue http://queue.acm.org/detail.cfm?id=2141937

Composability is an aspect of component design that addresses the freedom to select and combine generic components in nearly arbitrary configurations to support a wide…

Turing Award Lecture: John Backus A.M. Turing Award http://amturing.acm.org/award_winners/backus_0703524.cfm

Conventional programming languages are growing ever more enormous, but not stronger. Inherent defects at the most basic level cause them to be both fat and weak: their primitive word-at-a-time style of program- ruing inherited from their common ancestor--the von Neumann computer, their close coupling of semantics to state transitions, their division of programming into a world of expressions and a world of statements, their inability to effectively use powerful combining forms for building new programs from existing ones, and their lack of useful mathematical properties for reasoning about programs.

Tools

First Computer: Intel i80486 SX/25, 4 MiB RAM, 120 MB HDD
Favorite Editor: Visual Studio Code