NS2 is a most prominent tool to develop network, protocol and topology. We ensure NS2 as discrete event based simulator and have capacity to extend and modify.
NS2 provides users with a way of specifying such network protocols and simulating. Issariyakul and E. Hossain, Introduction to Network Simulator NS2. Ns2 installation in Ubuntu 18.04 Unlike earlier version of ubuntu, the 18,04 version does not support the direct installation of ns2, because of the latest C/C++ compiler (7.x), but the latest C/C++ compiler supported by ns2 is gcc-4.8.
We offer Ns2 projects in Pune for college students and research scholars under networking domain around pune. We support NS2 simulation to design new routing protocol with multicast function. We implement code in NS2 for network ensures more application developed in wireless network. We can provide compassion of single and multi routing protocol separately. Location Free Greedy Face Greedy Routing: In wireless network topology modification ensure change in node includes Run out of power, fail (or) join Network.
![Ns2 Network Simulator Ns2 Network Simulator](/uploads/1/2/5/4/125409636/794671623.jpg)
To ensure guarantee delivery in Network we use location free Greedy face greedy routing protocol which taken from the reference of Springer Papers. To create virtual network in unique network plane we have LFGFG with multivalued, multiple virtual nodes and multiple virtual links. We implement LF-GEG algorithm which works based on VN and spanning planner subgraph connection. We evaluated various performance metrics such as maintenance time; message overhead in more than 80+ projects by Ns2 simulation tool.
Internet Service Provider: To enhance efficiency we implement an important and effective way called internet service provider and peering. We use internet peering which reduce cost and reliance on purchased internet transit. ISP is used to reduce telecommunication cost. We use ISP to generate communication among end users and public business internet.
IPS Characteristics: We attain by implementing IPS are:. Lower Latency. Low Transmit Costs. Peering Process in ISP: We provide the goals to perform peering process are:-. Peering as soon as possible.
For various network architecture execute regional operation plans. Satisfy network connection in large business. Maximize benefits of systematic approach. Reduce cost for interconnection and Trans it process.
Optical Packet Network: We create optical packet network by various equipped switches with set of limited range wavelength converters. We use optional packet network scheduling algorithm to increase switch throughput. We provide M.Tech projects to overcome scheduling problem. We use maximum bipartite matching (MBM) with convex graph MBM algorithm mainly focused on switch level performance. We implement MBM with minimum edge to eradicate scheduling problem formation. We implement this algorithm by NS2 simulation. Random Early Demotion and Promotion: We use various services model to evaluate best effort internet with QoS and packet level differentiation.
We ensure end to service differentiation by per hop behavior basis. We adopt edge router in each domain to aggregate incoming packet flow and demote packet with inter domain service agreement. We permit random early demotion and promotion as:.
Demote Packets are easily detected and promoted. Every fair demotion packet depends on packet flows. REDP using 3 color marking scheme by NS2 simulation tool. We gave marking scheme as one color to differentiate demoted packet and packet with original out of profile. Ns2 Projects Work Progress.
MANET – Mobile Ad Hoc Network 95%. VANET – Vechicle Ad Hoc Netwok 97%. LTE – Long Term Evolution 78%. IoT – Internet of Things 90%. Wireless Sensor Network 89%. Network Security 89%.
Ns2 Attacks 96%. Cognitive Radio Network 85%. Parallel and Distributed Computing 73%. SDN – Software Defined Networking 95%. P2P, Video Streaming, Peersim 96%. IPV4, IPV6 88%.
4G Network, 5G Network 80%. Visual, Underwater Sensor Network 79%. Multicasting Communication 84%. Wimax, WiFi 90%. OFDMA 94%.
Reason to Choose NS2 Simulator Ns2 solution tech is a global project development and outsourcing Ns2 projects for students and clients. Ns2 solution tech works mostly in the NS2 research area. This offers students and research scholars to use our developer skills to develop an efficient Ns2 projects. We provide various innovative ideas with innovative solution for any kind of NS2 projects under network communication. Ns2 solution helps final year students of B.E, B.Tech, M.E and M.Tech and PhD Scholars. We provide 100% satisfaction with your projects and implementation in an effective way. Links To Ns2 Simulator Projects.
The Network Simulator ns-2: Building Ns version 2 The Network Simulator: Building Ns This page describes ns version 2. What hardware is needed? To build ns you need a computer and a C compiler. We develop ns on several kinds of Unix (FreeBSD, Linux, SunOS, Solaris), so it installs smoothest there, but it should run on an Posix-like computer, possibly with some tweaking. Ns also builds and runs under Windows, see the dedicated. Simple scenarios should run on any reasonable machine, but very large scenarios benefit from large amounts of memory.
Ns is fairly large. The allinone package requires about 320MB of disk space to build. Building ns from pieces can save some disk space. (If multiple people want to share files in the ns build tree to save space, you may download a, then follow the instruction in its README. There is from CS599b class of USC.
![Network Network](/uploads/1/2/5/4/125409636/707315526.jpg)
You may also find discussions in the ns-users mailing list archive useful.) How do I get the software? There are two ways to build ns:. If you just want to try it out quickly, you might try. If you want to do C-level developement, or save download time or disk space, or have trouble with all-in-one you should build it As of November, 2005, ns is available at.
Important: Please check the after you finish installation! Ns depends on several externally available components. Below is a summary of where to get them and where they may already be (if you're a VINT developer). Since the components depend on each other, you should build them in the listed order. Tcl/Tk Download source:. A modestly up to date Tcl/Tk version.
web page:. Note that while more up to date versions of Tcl/Tk are available and may work, we have only tested up through version 8.5.10.
Otcl Download source:. (package 'otcl').
web page:. TclCL (the package formerly known as libTcl) Download source:.
The latest version. (package 'tclcl'). web page:.
Ns-2 Download source:. (ns-2.35 released Nov 4 2011).,. (module 'ns-2'). There may be known problems with the current version of ns; please check the for patches. Nam-1 (optional) Download source:. (nam-1.15 released Nov 4 2011).,.
(module 'nam-1'). web page: You can find pre-built binary of nam-1.11 for Linux/freeBSD from the. Xgraph (optional, but needed for test suites) Download source:, or by (module 'xgraph').
(This version is maintained by the ns maintainers and includes portability fixes over the.) perl (optional, but needed for test suites) Download source:; web page: Note that version 5.003 or later is required. Tcl-debug (optional, available for Tcl debugging help) Download source:; web page:. This version will work with Tcl/Tk 8.0 release. Dmalloc (optional, available for memory debugging) Download source:.
Web page:; specify -with-dmalloc during configure to include. Sgb2ns conversion program (optional, needed to convert GT-ITM output to ns-2 format) Download source:. For more info on GT-ITM topology generators see. Tiers2ns conversion program (optional, needed to convert Tiers output to ns-2 format) Download source:. For more info on Tiers topology generators see.
Cweb and sgb source code (optional, required to create sgb-library that is used by gt-itm and sgb2ns programs) Download cweb source from Download sgb source code from VINT developers at ISI can find all of these packages in /nfs/filb2/public/pkgs. Building it From Sources These instructions are for Unix only. For Windows, the is recommended. Go for Windows instructions. Fetch the source code as described above. Unpack OTcl, TclCL and ns source into the same top level directory. build OTcl, TclCL and ns.
cd into the OTcl directory. run./configure. run make. cd into the TclCL directory. run./configure. run make. cd into the ns directory.
run./configure. run make For Unix, a simple./configure will try to auto-detect the packages ns needs to build. Auto-detection searchs sensible places (like /usr/local) and the directory above current direcory. If you have packages installed elsewhere you can explicitly tell ns where something is with options like -with-tcl=/your/path/to/tcl. Run./configure -help for a complete list of options.
Code. Verify that it built correctly and runs:./validate Ns-allinone is a package which contains equired components and some optional components used in running ns.
The package contains an 'install' script to automatically configure, compile and install these components. After downloading, run the install script. If you haven't installed ns before and want to quickly try ns out, ns-allinone may be easier than getting all the pieces by hand.