There are 0 repository under optoelectronics topic.
Optimization and inverse design of photonic crystals using deep reinforcement learning
Band diagram and Field of 2D photonic cristal
Optical Transfer Matrix Solver
Computes effective mode in a 2D wave guide
2D Time independent Schroedinger equation solver
Schrodinger-Poisson solver in 1D demonstrator
Optical Transfer Matrix Solver with index dispersion
Computes the threshold gain in various kind of cavity
Computes the electronic band structure of Zinc Blende semiconductor
Computes the electronic band structure of bulk ZB semiconductor with k.p models WITH STRAIN
Computes the electronic band structure of bulk ZB semiconductor with various k.p models
3D Time independent Schroedinger equation solver
1D Time independent Schroedinger equation solver
Computes effective mode in a 1D wave guide
1D Schroedinger solver in semiconductor with effective mass
1D Schroedinger solver in semiconductor with non-parabolicity
Computes eigen frequencies in a 2D micro-cavity
Computes the gain from interband laser diode
Computes the density of states in Bulk and quantum well
Computes eigen frequencies in a 3D micro-cavity
Computes the electronic band structure of bulk Wurtzite semiconductors
Poisson solver for semiconductor hetero-structures
Schrodinger-Poisson solver in 1D in the conduction band
Computes eigen frequencies in a 1D micro-cavity
1D Schroedinger solver in semiconductor with non-parabolicity in Zinc-Blende
Schrodinger-Poisson solver with Dirichlet boundary condition
2D time independent Schroedinger equation solver on inhomogeneous grid
This resiprocity contains my assignments on the graduate level course Semiconductor Optoelectronic Devices.
a compilation of notebooks for optoelectronics engineering
Master's Thesis in optoelectronics and silicon photonics in the scope of the T.I.M.E. Double Degree program between UCLouvain (Belgium) and Keio University (Japan).
This project aims to provide a very simple slow (~15KHz) but low noise photodiode front end, for the use in building scientific instrumentation.
Volume Local Analysis -- Chest Wall Plethysmography using Opto-Electronic Sensor Data
A tool created for optical and optoelectronic laboratory processes.
Sensors are widely used in many kinds of robotics systems for controlling, op- timizing, and monitoring the operation and the performance. They measure a large number of useful physical parameters. Among these, force and torque are primary measurements. This work presents a complete design and implementa- tion of the uni-axis force sensor. This force sensor is based on an optoelectronic sensor which is known as a light fork. This design can be used for various robotics applications to measure the force. The simplicity of design and its low cost, make it more feasible to measure the force applied by different robots by the deformation of a properly designed mechanical structure integrated into the actuation module. This force sensor provides good linearity and sensitivity for the applied force. The work contains the complete scheme of electronics schematics with PCB design. The electronics design contains the STM32f405 microcontroller, which has internal memory to save the calibration data. The mechanical design is also described in this work with proper dimension and length to construct the obstacle and case of the sensor. The design of the sen- sor can be modified for calibration and integration with the robotics module. The methodology of this work describes the basic working principle and also a proper mechanism to measure the force applied on the top surface of the sensor with the arrangement of four optoelectronics sensors.