[TutsNode.com] - Computational Physics Scientific Programming with Python

  11 - [Add on] Nobel prize lecture Electronic properties of graphene

   009 Applying magnetic field Landau quantization & Quantum Hall effect.mp4

   012 11-Graphene.ipynb

   002 11-Graphene-template.ipynb

   003 From free electrons to band structures_en.srt

   009 Applying magnetic field Landau quantization & Quantum Hall effect_en.srt

   004 Plotting a graphene lattice_en.srt

   006 Dirac points and massless electrons_en.srt

   010 Moire lattice of twisted bilayers of graphene_en.srt

   011 Section recap_en.srt

   012 Resources & Links.html

   004 Plotting a graphene lattice.mp4

   001 Introduction.mp4

   011 Section recap.mp4

  01 - Python installation via Anaconda & Alternatives

   008 (FAQ) Typical problems & errors.html

   007 LET'S GET STARTED with scientific programming!.html

   002 Overview.png

   010 (optional) Alternative development environments For large projects - PyCharm_en.srt

   011 (optional) Alternative development environments Allrounder - Visual Studio Code_en.srt

   002 Structure & Overview of this course_en.srt

   009 (optional) Style sheets for your notebook.mp4

   002 Structure & Overview of this course.mp4

   006 HOW TO use this course.mp4

   004 Jupyter notebook - Our tool of choice.mp4

   012 (optional) Environments & Updates.mp4

  10 - [Add On] Quantum mechanics Solving the Schrödinger equation

   012 10a-Particle-in-a-box.ipynb

   008 Determining & Discussing the eigensystem of the quantum harmonic oscillator_en.srt

   008 Determining & Discussing the eigensystem of the quantum harmonic oscillator.mp4

   004 Finding the first solution via the shooting method_en.srt

   010 Use Mathematica to solve the problem with only a few lines of code_en.srt

   001 Introduction_en.srt

   006 [Project] Quantum harmonic oscillator.html

   012 Resources & Links.html

   007 Adapting our notebook to the new potential.mp4

   011 Section recap.mp4

  07 - Differential equations II Multiple dimensions

   011 Solving the heat equation in two dimensions_en.srt

   023 07b-Multidimensional-lorenz.ipynb

   011 Solving the heat equation in two dimensions.mp4

   002 07a-Multidimensional-rolling-ball-template.ipynb

   021 Brake maneuver to reach moon orbit_en.srt

   010 Solving the heat equation in one dimension_en.srt

   004 Solving the differential equation of a rolling ball_en.srt

   007 Solving the Lorenz differential equation for the chaotic case_en.srt

   017 [Project] Rocketship - Coding & Solving the differential equations_en.srt

   005 Different starting conditions & external forces acting on the ball_en.srt

   012 [Project] 3-body problem Coupled differential equations for sun, earth & moon_en.srt

   002 07d-Mutidimensional-3-body-template.ipynb

   018 Changing starting velocity Elliptical orbit around earth_en.srt

   020 Simulating a moon encounter_en.srt

   023 07c-Multidimensional-heat-equation-template.ipynb

   008 Solving the Lorenz differential equation for the non-chaotic case_en.srt

   016 Comment on inclination of the moon_en.srt

   022 Section recap_en.srt

   015 Analyzing the orbital motion of earth & moon.mp4

   004 Solving the differential equation of a rolling ball.mp4

   013 Coding the differential equations for sun, earth & moon.mp4

   017 [Project] Rocketship - Coding & Solving the differential equations.mp4

   018 Changing starting velocity Elliptical orbit around earth.mp4

   003 [Project] Simulating a rolling ball - Two decoupled oscillators.mp4

   020 Simulating a moon encounter.mp4

   012 [Project] 3-body problem Coupled differential equations for sun, earth & moon.mp4

   022 Section recap.mp4

   016 Comment on inclination of the moon.mp4

  06 - Differential equations I Basics and 1-dimensional problems

   004 Example 1 Radioactive decay_en.srt

   014 Compare different methods for solving differential equations_en.srt

   002 06-Differential-equations-template.ipynb

   012 Improvement Use the SciPy function solve_ivp_en.srt

   007 Higher-order differential equations_en.srt

   009 Example 4 Pendulum_en.srt

   002 Template file.html

   006 Example 2 Time-amplified radioactive decay_en.srt

   016 Implementation of RK45_en.srt

   019 Resources & Links.html

   010 Accurate solution of the pendulum_en.srt

   015 Implementation of Runge Kutta 4th order method.mp4

   017 Comparison of our three methods to solve differential equations.mp4

   005 Defining a general function for the Euler method.mp4

   009 Example 4 Pendulum.mp4

   013 Higher-order differential equations with solve_ivp.mp4

   016 Implementation of RK45.mp4

   008 Example 3 Free fall.mp4

   003 Background Euler method.mp4

  02 - [Optional] Python Crash Course

   001 Introduction to section Optional Python crash course_en.srt

   006 [Solution] Coding Exercise Basic programming sqrt.html

   019 Resources & Links.html

   002 02-Crash-course-template.ipynb

   016 Density plot_en.srt

   011 Loops & If statements_en.srt

   008 Arrays_en.srt

   017 3D Plots_en.srt

   004 Data types of numbers_en.srt

   003 Numpy & Basic mathematics_en.srt

   014 [Solution] Coding Exercise Implement a function with loops.html

   016 Density plot.mp4

   008 Arrays.mp4

   013 Functions.mp4

   011 Loops & If statements.mp4

   001 Introduction to section Optional Python crash course.mp4

   003 Numpy & Basic mathematics.mp4

   005 Strings.mp4

  09 - Monte Carlo algorithms

   014 09b-MC-magnet.ipynb

   006 [Project] Simulating a magnet - Setting up & plotting the initial state_en.srt

   006 [Project] Simulating a magnet - Setting up & plotting the initial state.mp4

   012 Dzyaloshinskii–Moriya interaction giving rise to non-collinear spin textures_en.srt

   002 09a-MC-pi-template.ipynb

   004 Approximating Pi using a Monte Carlo algorithm_en.srt

   010 Improve code using finite temperatures_en.srt

   003 [Project] Calculating Pi - Explaining the idea_en.srt

   002 09b-MC-magnet-template.ipynb

   002 Template files.html

   013 Section recap_en.srt

   007 Defining the energy.mp4

   009 Running the Monte Carlo algorithm.mp4

   001 Introduction.mp4

   005 Alternative solution and time comparison for approximating Pi.mp4

   013 Section recap.mp4

  04 - Derivatives

   002 figure-04-derivatives.png

   010 04b-Exercise-velocity-acceleration-data-file.dat

   014 figure-04-derivatives.png

   006 Better accuracy Richardson method.mp4

   009 04b-Exercise-velocity-acceleration.ipynb

   006 Better accuracy Richardson method_en.srt

   009 Exercise files Calculate velocity and acceleration.html

   014 04b-Exercise-velocity-acceleration.ipynb

   010 04b-Exercise-velocity-acceleration-solution.ipynb

   002 04a-Derivatives-template.ipynb

   008 [Exercise] Calculate velocity and acceleration_en.srt

   011 Multidimensional derivatives Gradient_en.srt

   012 Multidimensional derivatives Divergence & curl_en.srt

   001 Introduction_en.srt

   004 Implementation of derivatives in Python.mp4

   011 Multidimensional derivatives Gradient.mp4

   012 Multidimensional derivatives Divergence & curl.mp4

   008 [Exercise] Calculate velocity and acceleration.mp4

  08 - Eigenvalue problems

   014 08-Eigenvalue-coupled-oscillators.ipynb

   002 figure-08-coupled-oscillators-circle.png

   007 [Solution] Write your own routine to calculate the eigenvalues_en.srt

   014 figure-08-coupled-oscillators.png

   011 [Solution] Fit three harmonic oscillations to our numerical solution.mp4

   014 08-Eigenvalue-coupled-oscillators-template.ipynb

   012 Generalization to n coupled oscillators_en.srt

   005 Why is it an eigenvalue problem_en.srt

   008 Analyzing the eigenmodes of the three coupled oscillators_en.srt

   001 Introduction_en.srt

   002 Template file.html

   009 Fourier transform Find the characteristic frequencies of the numerical solution.mp4

   004 Numerical solution of the coupled differential equations.mp4

   003 Three coupled oscillators Equations of motion.mp4

   005 Why is it an eigenvalue problem.mp4

   010 [Exercise] Fit three harmonic oscillations to our numerical solution.mp4

  03 - Series expansion, interpolation & data fitting

   018 03-Interpolation.ipynb

   002 Template file.html

   017 Section recap_en.srt

   010 Perfect interpolation using polynomials - Solving a system of linear equations_en.srt

   003 Taylor expansion of exponential function_en.srt

   014 Calculating the gradient of the error_en.srt

   007 Interpolation_en.srt

   009 Using splines to fit perturbed data_en.srt

   002 03-Interpolation-template.ipynb

   004 Taylor expansion of sin function_en.srt

   010 Perfect interpolation using polynomials - Solving a system of linear equations.mp4

   014 Calculating the gradient of the error.mp4

   003 Taylor expansion of exponential function.mp4

   009 Using splines to fit perturbed data.mp4

   008 Linear and cubic splines.mp4

   013 Calculating the fitting error.mp4

   012 Fitting a polynomial model function.mp4

  05 - Integrals

   020 Fourier transform_en.srt

   023 05b-Rotation-geometric-objects.ipynb

   023 05c-Magnetic-field-wire.ipynb

   002 figure-05-integral.png

   023 figure-05-integral.png

   002 figure-05-hand.svg

   002 05d-Fourier-transform-template.ipynb

   017 Calculating the magnetic field of a charged wire_en.srt

   006 [Project] Rotational energy & Moment of inertia - Start with a point mass_en.srt

   001 Introduction_en.srt

   008 [Exercise] Rotating a stick around the center_en.srt

   010 Rotating a sphere Analytical solution_en.srt

   014 [Project] Magnetic field of a wire - Explaining the problem_en.srt

   002 05b-Rotation-geometric-objects-template.ipynb

   003 Background on integrals_en.srt

   022 Section recap_en.srt

   023 05a-Basics-integration-template.ipynb

   018 Quiver plot of the magnetic field_en.srt

   023 05c-Magnetic-field-wire-template.ipynb

   009 [Solution] Rotating a stick around the center_en.srt

   012 [Exercise] Rotating a spherical shell_en.srt

   011 Rotating a sphere Numerical solution.mp4

   004 Discretizing integrals & Trapezoidal method.mp4

   020 Fourier transform.mp4

   005 Improving accuracy Simpson rule and beyond.mp4

   014 [Project] Magnetic field of a wire - Explaining the problem.mp4

   010 Rotating a sphere Analytical solution.mp4

   013 [Solution] Rotating a spherical shell.mp4

   009 [Solution] Rotating a stick around the center.mp4

   012 [Exercise] Rotating a spherical shell.mp4

   008 [Exercise] Rotating a stick around the center.mp4

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