基于windows input simulator http://inputsimulator.codeplex.com/，在其中添加了鼠标模拟事件。注意是C#代码。 此包可用于在windows下模拟键盘事件及鼠标事件。遵守Microsoft Public License (Ms-PL)

The MRSim (Multi-Robot Simulator) is an extension of the Autonomous mobile robotics toolbox SIMROBOT (SIMulated ROBOTs) created for MatLab 5 in 2001. MRSim allows the user to simulate the behavior of multiple mobile robots in virtual environments. When compared to its predecessor SIMROBOT, MRSim presents two key contributions: 1) It is fitted to the new MatLab versions - Previously, users were unable to work with SIMROBOT functions since most of them were incompatible with the new MatLab versions. MatLab significantly evolved over the last 10 years, making SIMROBOT obsolete. In this extension, all features of SIMROBOT were updated and improved based on the new MatLab functions; 2)It is also fitted to suit multi-robot applications - although SIMROBOT was endowed with various interesting features for mobile robotics, it presented several limitations for multi-robot applications. Therefore, MRSim was created primarily to allow users to develop multi-robot applications, which would benefit working with some specific requirements such as multi-hop communication. Moreover, most of the functionalities in MRSim have an integrated help (which can be accessed just by typing help function) that allows to easily understand the dynamics of how to create and run simulations. In sum, just like SIMROBOT, each robot in MRSim can be equipped with several virtual sensors and can be driven by its own control algorithm. The toolbox includes two independent applications. The first one is the EDITOR (simedit), which allows the user to create and modify the virtual environment,to edit the control algorithms of robots, to load and save simulation, and others. The second application, SIMULATOR (simview), can be run directly from the EDITOR or separately from MatLab Command Window and serves as a simulation viewer. A MatLab help file is being currently created and will be add in the future.

误码率曲线matlab代码IEEE 802.11a PHY模拟器 该模拟器由构成IEEE 802.11a协议物理层的几个部分集成在一起。 典型调制：BPSK / 16QAM 运行“ main.m”将在控制台中运行程序 运行'app1.mlapp'将运行集成的应用程序（GUI） 协议的详细信息可以在参考中找到 脚本描述 add_cp->添加循环前缀 delete_cp->删除循环前缀 add_pilot->添加飞行员频率 coding_conv->卷积编码 coding_conv->维特比解码 cons_map->星座映射 decons_map->星座逆映射 交织->交织 解交织->解交织 序言->添加序言 争夺->争夺 解密->解密 IFFT64-> OFDM调制 FFT64-> OFDM解调 syn->同步 ber_curve-> BER曲线产生器 计数->计数器 主要的 环境 MATLAB R2019a（更新2），包括App Designer 参考 IEEE标准802.11:trade_mark:-2007 IEEE信息技术标准—系统之间的电信和信息交换—局域网和城域网—特定要求，第11部分：无线局域网

巴恩斯小屋模拟器 使用Barnes-Hut-Algorithm有效解决N体问题。 此源代码库属于上的一篇文章，解释了Barnes-Hut算法。 有关详细信息，请查阅原始文章。 英文版： ：

SNMP Simulator是一种软件，从SNMP Manager的角度来看，它就像许多实际的物理设备一样。 模拟器可以建立并使用物理设备的SNMP足迹数据库进行响应，就像它们的真实对手一样。 项目移至GitHub：https：//github.com/etingof/snmpsim

This assignment is designed to give us a better understanding about cache behavior. We will write a cache simulator using C programming language. This assignment is much complex than it looks like. Be careful! It will require a substantial implementation effort as well as time and effort to explore and analyze cache behaviors. The usual warning goes double for this assignment: do not procrastinate.

gravity_simulator

Gravity-Simulator, 在JS中，2D 牛顿重力模拟器 希望帮助或者修改这里项目？提交请求请求，它可能会被接受 ！代码结构如何？我使用AMD模块系统构建应用程序，特别是我使用 require.js 作为模块加载程序有三个独立的模块 js/gravity/spacetime.js存储

该应用程序最初是对牛顿物理学的研究，但后来演变为太阳系的2D模拟。 （从南方观看，因为如果没有大的红点，木星就不会成为木星。）源代码可供想要进行自己的自定义和独特方案（例如在太阳系中发送黑洞）的开发人员使用。 对于临时用户，此程序使您可以真正熟悉太阳系。 驾驶一艘载有无限燃料的太空船，有许多刻度盘可将您引导到目的地，而不必担心一个较小的维度，您可以在太阳系中旅行时亲身体验广阔的距离，巨大的速度和巨大的引力。 然而，您会发现太空旅行仍然需要掌握高超的技巧和耐心。 但是，当您阅读报纸上的太空故事时，它也为您提供了一个了解这些庞大数字的环境。 也是使孩子们对太空感兴趣的好工具。

go语言并行模拟万有引力天体运行 使用golang+js实现的万有引力模拟程序。(N体计算方式) 服务端使用go利用多核并行计算，支持memcache/redis/file存储计算数据，前后端使用websocket通信，前端使用ThreeJS框架，利用WebGL显示3D效果。 可模拟恒星系统，球状星团，星系，星流等 可设置中心超大质量天体(黑洞) 可合并多个集合，比如合并椭球星系和螺旋星系 可批量操作参数，比如放大分布范围，加快速度，增加质量，用来把球状星团放大到星系尺度等模拟 可保存和加载模拟的N体对象 效果图： 思路： 有两个程序,calc_server和websocket_server calc_server -> 计算数据保存到file/mc/redis 浏览器查看 -> websocket_server ->读取file/mc/redis的数据 查看需要浏览器支持WebGL,比如