oscillators | Topic | Ecosyste.ms: Repos

Topic: "oscillators"

everget/tradingview-pinescript-indicators

A collection of the various technical indicators implemented in Pine Script Language

Size: 187 KB - Last synced at: about 1 month ago - Pushed at: about 1 month ago - Stars: 585 - Forks: 166

MikeMorenoDSP/pd-mkmr

A compilation of abstractions and instruments compatible with Pure Data vanilla.

Language: Tcl - Size: 4.84 MB - Last synced at: 8 days ago - Pushed at: about 1 year ago - Stars: 267 - Forks: 27

AudioKit/SoundpipeAudioKit

C-based instruments and effects for AudioKit

Language: C - Size: 3.2 MB - Last synced at: 27 days ago - Pushed at: 4 months ago - Stars: 120 - Forks: 44

lukehorvat/web-audio-oscillators

A collection of Web Audio API custom oscillators.

Language: TypeScript - Size: 119 KB - Last synced at: about 1 month ago - Pushed at: 11 months ago - Stars: 65 - Forks: 5

QuantumEngineeredSystems/HarmonicBalance.jl

A Julia package for solving nonlinear differential equations using the harmonic balance method.

Language: Julia - Size: 66.4 MB - Last synced at: 9 days ago - Pushed at: 9 days ago - Stars: 64 - Forks: 17

delosh653/ECHO

An application to find and visualize circadian rhythms in time course data using extended harmonic oscillators.

Language: R - Size: 6.86 MB - Last synced at: 23 days ago - Pushed at: almost 5 years ago - Stars: 14 - Forks: 0

MuonRay/QuantumNetworkSimulations

A series of simulation codes used to emulate quantum-like networks in the simulation of emergent adaptive behavior, such as network synchronization, and relate the nature of the coupled harmonic oscillators with non-local behavior and chimera states in systems of quantum particles. Coding Used is based on mathematical modelling of transport in quantum many-body systems and networks made tractable using the quantum newtons cradle. A full showcase of this project is discussed in the following videos:https://www.youtube.com/watch?time_continue=115&v=WX3Ds_xCOaE

Language: Python - Size: 1.2 MB - Last synced at: about 1 month ago - Pushed at: 9 months ago - Stars: 13 - Forks: 2

yarpose/YARPOSE.ML-Communication.Circuits

A Full open-source/Full with Python/ interactive course for all who like to know "What are Communication Circuits?" from scratch to basic applications.

Language: Jupyter Notebook - Size: 8.51 MB - Last synced at: about 1 month ago - Pushed at: over 1 year ago - Stars: 12 - Forks: 2

liopic/logue-osc-fx

Custom oscillators and effects for Korg NTS-1, minilogue xd, prologue and other logue-sdk based synths

Language: Makefile - Size: 20.5 KB - Last synced at: about 2 months ago - Pushed at: almost 4 years ago - Stars: 12 - Forks: 0

tomaslink/frequenpy

High-precision physics engine dedicated to the study of standing waves and visualization of its normal modes.

Language: Python - Size: 604 KB - Last synced at: 4 days ago - Pushed at: over 1 year ago - Stars: 10 - Forks: 0

narner/Arduino-AudioKitOSX 📦

A simple FM oscillator controlled by an Arduino circuit via serial data.

Language: Objective-C - Size: 58.4 MB - Last synced at: 1 day ago - Pushed at: over 5 years ago - Stars: 9 - Forks: 1

victimofleisure/PotterDraw

Design your own pottery for 3D printing in full color.

Language: C++ - Size: 7.63 MB - Last synced at: over 1 year ago - Pushed at: over 2 years ago - Stars: 4 - Forks: 3

tud-phi/uncovering-iss-coupled-oscillator-networks-from-pixels

[NeurIPS 2024] Input-to-State Stable Coupled Oscillator Networks for Closed-form Model-based Control in Latent Space

Language: Python - Size: 15.3 MB - Last synced at: 4 months ago - Pushed at: 4 months ago - Stars: 3 - Forks: 0

calinalexandru/audio-diagrams

Interactive tool for visually creating and testing Web Audio API routing graphs across different browsers.

Language: JavaScript - Size: 693 KB - Last synced at: over 1 year ago - Pushed at: over 1 year ago - Stars: 3 - Forks: 0

cayscays/Oscillators-7x7-Dataset-Game-of-Life

A dataset of 7x7 oscillators in Conway's Game of Life, providing a comprehensive resource for analysis and study.

Language: Jupyter Notebook - Size: 46.9 KB - Last synced at: about 2 months ago - Pushed at: about 2 months ago - Stars: 2 - Forks: 0

cayscays/Neural-Network-From-Scratch

Implementation of a customizable neural network for classification tasks. Projects in this repo include medical data analysis and pattern classification in a cellular automaton environment.

Language: Python - Size: 310 KB - Last synced at: about 1 year ago - Pushed at: about 1 year ago - Stars: 2 - Forks: 0

Zhjy1/Literature-Review-of-Oscillators

A Brief Literature Review of Oscillators

Language: TeX - Size: 2.75 MB - Last synced at: over 1 year ago - Pushed at: over 1 year ago - Stars: 2 - Forks: 0

kiavash-at-home/10GHz-DRO 📦

Designed and built of a 10GHz Dielectric Oscillator

Size: 988 KB - Last synced at: 11 months ago - Pushed at: over 3 years ago - Stars: 2 - Forks: 1

keble6/singingcoach

A web app to help you to keep in tune

Language: JavaScript - Size: 116 KB - Last synced at: almost 2 years ago - Pushed at: almost 5 years ago - Stars: 2 - Forks: 1

Nebulean/Simulation-oscillateurs-harmoniques

Simulations d'oscillateur harmonique, réalisé dans le cadre d'un projet d'informatique à l'EPFL.

Language: C++ - Size: 927 KB - Last synced at: over 1 year ago - Pushed at: almost 7 years ago - Stars: 2 - Forks: 0

glennforrest/oscillators

Experimenting with web audio API & oscillators

Language: Vue - Size: 894 KB - Last synced at: about 2 years ago - Pushed at: over 2 years ago - Stars: 1 - Forks: 0

dakofler/Swarmalators

Simulation of the Swarmalator Model and exploring methodes to achieve faster convergence using an additive momentum term

Language: Python - Size: 162 KB - Last synced at: almost 2 years ago - Pushed at: over 2 years ago - Stars: 1 - Forks: 0

stewdio/darkwave

Chunky analog synth sounds from your guitar fretboard.

Language: JavaScript - Size: 104 KB - Last synced at: 27 days ago - Pushed at: about 4 years ago - Stars: 1 - Forks: 0

nick8055/DIY-CNC-Winding-Machine

I have created a PYTHON program (around 1000 lines of code) for my Raspberry Pi 4 to automate an old, purely mechanical winding machine for winding coils using copper wire, mainly used for the purpose of motors/generators, etc. Initially, you would have to manually wind your coils mechanically by using your right hand to turn the spindle, which rotates the attached bobbin, and the wire fed through the wire guide gets wound over the bobbin. The rotation of the main spindle would also result in the horizontal movement of the wire guide, since the gear of the spindle is mechanically linked to that of the wire guide, through a series of pulleys , rubber bushes, gears, etc. The issue is that, its not all that precise, since you could still encounter overlappings, or gap formations, while winding. Therefore, you would have to carefully wind coils to ensure no gaps or overlaps occur by slowly rotating the spindle with your hand, while paying attention to the winding process, which would take eons to wind one coil, as well as a lot of tiresome and stress. But with retrofitting, most of the above mentioned issues have been nullified. With a pair of stepper motors, stepper drivers, frequency generators, encoders, and a single-board computer to command all these components, it is a BREEZE. One stepper motor connected to the main spindle which rotates the bobbin, another stepper motor which controls the wire guide horizontal travel (right or left). Respective stepper drivers are connected to drive these motors, so that input is given to these drivers, which would drive the motors. Using these drivers, we can alter the speed of the motors, the direction (clockwise or anti-clockwise), as well as enable/disable the motors. A frequency input is given to the driver to spin the motor at desired RPMS. Initially, I generated the frequency from the Raspberry Pi , but found out to be unstable and erratic. Therefore, separate digital frequency oscillators had to be used to produce the frequency steadily. These oscillators support UART protocol, so I was able to interface them with the Raspberry Pi via the Serial communication bus. The Raspberry Pi sends commands under a certain format to these frequency oscillators to change the frequency as well as the duty cycle of their outputs, which are given as inputs to the respective motor drivers. This way, Raspberry Pi can act as the Brain, while the donkey work is done by those oscillators. These two oscillators are mathematically linked using a formula based on the wire thickness used for the winding, which is specified in the PYTHON script. This way, depending on what speed was set for the main spindle motor, the speed motor of the wire-guide goes at a ratio, thereby reducing the chance of overlaps or gap formations while winding. With this setup, you don't have to use your hand to rotate the spindle. It does everything automatically, although you have to keep an eye while the process is going on, incase something happens. You can pause in between in order to sort any kind of issue. The wire guide direction changes automatically after covering each layer, from left to right, and vice-versa. A coil which would normally take 2 hours to be wound precisely, would just take 30 minutes to be wound on a retrofitted machine like this.

Language: Python - Size: 10.3 MB - Last synced at: over 1 year ago - Pushed at: about 4 years ago - Stars: 1 - Forks: 1