This document describes the process for leveraging the ClearPass Guest captive portal to bypass the Captive Network Assistant (web sheet) that is displayed on iOS devices such as iPhone, iPad, and more recently, OS X machines running Lion (10.7) and above.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
This document describes the process for leveraging the ClearPass Guest captive portal to bypass the Captive Network Assistant (web sheet) that is displayed on iOS devices such as iPhone, iPad, and more recently, OS X machines running Lion (10.7) and above.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
The Indoor 802.11n Site Survey and Planning guide covers the design and installation of an Aruba WLAN. It includes information on choosing the right AP, performing a virtual survey, and performing a physical survey. The guide also covers using the Aruba Instant AP for physical site surveys.
This Solution Guide describes best practices for implementing an Aruba 802.11 wireless network that supports thousands of highly mobile devices (HMDs) such as Wi-Fi phones, handheld scanning terminals, voice badges, and computers mounted to vehicles. It describes the design principles particular to keeping devices that are in constant motion connected to the network as well as best practices for configuring Aruba Networks controllers and the mobile devices. The comprehensive guide addresses six areas of network planning to ensure a high quality of service for roaming data and voice sessions: device configuration, airtime optimization, roaming optimization, IP mobility configuration, IP multicast configuration, and interference resistance. A detailed troubleshooting section covers common issues that arise with these types of WLANs.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
This guide covers indoor 802.11n WLANs and is considered part of the foundation guides within the VRD core technologies series. This guide describes 802.11n, differences in 802.11n vs. 802.11a/b/g functionality, and Aruba-specific technologies and access points (APs) that make 802.11n-based WLANs a viable replacement for wired Ethernet in the majority of deployments.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
This lab setup document emulates the recommended campus and remote access point networks discussed in the Aruba Campus Networks Validated Reference Design and the Aruba Remote Access Point (RAP) Networks Validated Reference Design. All the screenshots and command-line interface (CLI) configurations in the Aruba Campus Networks Validated Reference Design and the Aruba Remote Access Point (RAP) Networks Validated Reference Design are from this setup.
Point-to-point (PTP) wireless connections have many use cases including linking buildings on university campus, creating connections between offshore oil rigs, and eliminating the need to pull fiber cable between buildings on opposite sides of a busy road. This guide will help you select the right hardware platform (including both the AOS-based AP-175 and Aruba¹s new AirMesh products; Choose appropriate antennas and accessories; Identify and overcome some of the most common outdoor installation challenges; Set up and configure the Aruba solution.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
This guide covers the deployment of Aruba WLAN in a typical campus network, and it is considered part of the base designs guides within the VRD core technologies series. This guide covers the design recommendations for a campus deployment and it explains the various configurations needed to implement the Aruba secure, high-performance, multimedia grade WLAN solution in large campuses.
This guide explains how to implement an Aruba 802.11n wireless network that must provide high-speed access to an auditorium-style room with 500 or more seats. Aruba Networks refers to such networks as high-density wireless LANs (HD WLANs). Lecture halls, hotel ballrooms, and convention centers are common examples of spaces with this requirement. Because the number of concurrent users on an AP is limited, to serve such a large number of devices requires access point (AP) densities well in excess of the usual AP per 2,500 – 5,000 ft2 (225 – 450 m2). Such coverage areas therefore have many special technical design challenges. This validated reference design provides the design principles, capacity planning methods, and physical installation knowledge needed to successfully deploy HD WLANs.
For WLANs to be able to reliably support mission-critical, high-throughput, or time-sensitive applications, RF interference must be continuously monitored. The WLAN must automatically and dynamically adapt to mitigate the effects of any interference in the environment. WLAN infrastructure has to provide the administrators with real-time, historical, and proactive visibility into the air to diagnose and mitigate interference. In this application note we will look at some of the tools that Aruba offers as a part of its WLAN solution that enable administrators to ensure reliable, high performing RF.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
The Aruba Mobility Access Switch family of products provides various features including voice VLAN, Link Layer Discovery Protocol – Media Endpoint Discovery (LLDP-MED), and Quality of Service (QoS) to enable successful deployment of VoIP in enterprise networks. This application note addresses traditional techniques and introduces new device-aware support to deploy VoIP phones. This document is intended for all system engineers and network administrators who are deploying a VoIP solution in an enterprise network.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
This guide covers Aruba Mobility Controllers and is considered part of the foundation guides within the VRD core technologies series. This guide will help you understand the capabilities and options you have when deploying an Aruba Mobility Controller. This guide describes operating modes for the mobility controller, licensing, forwarding modes, logical and physical deployment, redundancy, and how to select the appropriate mobility controller based on scalability requirements. Version 9 includes information on the 7200 series controller.
The Indoor 802.11n Site Survey and Planning guide covers the design and installation of an Aruba WLAN. It includes information on choosing the right AP, performing a virtual survey, and performing a physical survey. The guide also covers using the Aruba Instant AP for physical site surveys.
This Solution Guide describes best practices for implementing an Aruba 802.11 wireless network that supports thousands of highly mobile devices (HMDs) such as Wi-Fi phones, handheld scanning terminals, voice badges, and computers mounted to vehicles. It describes the design principles particular to keeping devices that are in constant motion connected to the network as well as best practices for configuring Aruba Networks controllers and the mobile devices. The comprehensive guide addresses six areas of network planning to ensure a high quality of service for roaming data and voice sessions: device configuration, airtime optimization, roaming optimization, IP mobility configuration, IP multicast configuration, and interference resistance. A detailed troubleshooting section covers common issues that arise with these types of WLANs.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
This guide covers indoor 802.11n WLANs and is considered part of the foundation guides within the VRD core technologies series. This guide describes 802.11n, differences in 802.11n vs. 802.11a/b/g functionality, and Aruba-specific technologies and access points (APs) that make 802.11n-based WLANs a viable replacement for wired Ethernet in the majority of deployments.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
This lab setup document emulates the recommended campus and remote access point networks discussed in the Aruba Campus Networks Validated Reference Design and the Aruba Remote Access Point (RAP) Networks Validated Reference Design. All the screenshots and command-line interface (CLI) configurations in the Aruba Campus Networks Validated Reference Design and the Aruba Remote Access Point (RAP) Networks Validated Reference Design are from this setup.
Point-to-point (PTP) wireless connections have many use cases including linking buildings on university campus, creating connections between offshore oil rigs, and eliminating the need to pull fiber cable between buildings on opposite sides of a busy road. This guide will help you select the right hardware platform (including both the AOS-based AP-175 and Aruba¹s new AirMesh products; Choose appropriate antennas and accessories; Identify and overcome some of the most common outdoor installation challenges; Set up and configure the Aruba solution.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
This guide covers the deployment of Aruba WLAN in a typical campus network, and it is considered part of the base designs guides within the VRD core technologies series. This guide covers the design recommendations for a campus deployment and it explains the various configurations needed to implement the Aruba secure, high-performance, multimedia grade WLAN solution in large campuses.
This guide explains how to implement an Aruba 802.11n wireless network that must provide high-speed access to an auditorium-style room with 500 or more seats. Aruba Networks refers to such networks as high-density wireless LANs (HD WLANs). Lecture halls, hotel ballrooms, and convention centers are common examples of spaces with this requirement. Because the number of concurrent users on an AP is limited, to serve such a large number of devices requires access point (AP) densities well in excess of the usual AP per 2,500 – 5,000 ft2 (225 – 450 m2). Such coverage areas therefore have many special technical design challenges. This validated reference design provides the design principles, capacity planning methods, and physical installation knowledge needed to successfully deploy HD WLANs.
For WLANs to be able to reliably support mission-critical, high-throughput, or time-sensitive applications, RF interference must be continuously monitored. The WLAN must automatically and dynamically adapt to mitigate the effects of any interference in the environment. WLAN infrastructure has to provide the administrators with real-time, historical, and proactive visibility into the air to diagnose and mitigate interference. In this application note we will look at some of the tools that Aruba offers as a part of its WLAN solution that enable administrators to ensure reliable, high performing RF.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
The Aruba Mobility Access Switch family of products provides various features including voice VLAN, Link Layer Discovery Protocol – Media Endpoint Discovery (LLDP-MED), and Quality of Service (QoS) to enable successful deployment of VoIP in enterprise networks. This application note addresses traditional techniques and introduces new device-aware support to deploy VoIP phones. This document is intended for all system engineers and network administrators who are deploying a VoIP solution in an enterprise network.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
This guide covers Aruba Mobility Controllers and is considered part of the foundation guides within the VRD core technologies series. This guide will help you understand the capabilities and options you have when deploying an Aruba Mobility Controller. This guide describes operating modes for the mobility controller, licensing, forwarding modes, logical and physical deployment, redundancy, and how to select the appropriate mobility controller based on scalability requirements. Version 9 includes information on the 7200 series controller.
An ambitious Networks, Systems, Cloud & Virtualization Solution Architect with more than 9 years of experience, having in-depth exposure of Plan, Design, Implement, commission and managing the CISCO, HP, FORTINET, SONICWALL, HUAWEI, JUNIPER ETC. convergence networks with state of art Routing & Switching, Security, Voice, Wireless technologies, Microsoft enterprise platforms and multi-tenancy cloud computing infrastructure with IT management & technical documentation skills. Willing to relocate & travel worldwide.
1. Manojkumar R
mano.kr170@outlook.com
9488300170, 9560600170
Objective:
To seek a challenging technical position in a pleasant working environment, which allows me continue
expanding my skill sets and knowledge as a Network VOIP Engineer.
Professional Experience:
Organization: HCL infosystems Pvt ltd
Location: Newdelhi, Hyderabad
CISCO VOIP Engineer, Since May 2013- Present.
Description:
HCL infosystems Pvt ltd, Supports technically with hardware AMC for IP network implemented and
designed under project name AFNET .To INDIAN AIR FORCE loaded with more or less about 300 sites on
12 CUCM clusters ,running in productivity.
Responsibilities:
Configuring and troubleshooting devices on VOIP network through Cisco Unified Communication
Manager.
Configuring, Troubleshooting and providing support of CISCO IPT for various clients.
Configuring and troubleshooting CISCO PSTN gateways and VEGA Analog Voice Gateways.
Configuring and troubleshooting over signaling methods PULSE, DTMF.
Configuring and Troubleshooting over POTS, Dial plans and Dial peers.
Configuration of Voice Interfaces: FXS, FXO, E1/T1.
Resolving day to day level 1 issues and configuration on CISCO jabber.
Monitoring and troubleshooting of Voice Gateways, SRST and call signaling protocols on
Voice Gateways H.323, MGCP, and SCCP.
Configuring and troubleshooting of TFTP,FTP and DHCP Servers.
Configuring phones through BAT-Bulk Administration Tool
Implementation, up gradation and testing of new VOIP hardware/software products over the VOIP
network.
Troubleshooting issues faced on PAGING system configured.
Server hardware maintenance, installation and trouble shooting (HP MCS series).
Configuring and troubleshooting bridged network connected through ATRIE DSLAM.
Ensuring any product related issue/incident is being resolved within the defined SLA. The job
demands me to avoid unwanted down of telephony/data services on the user end.
2. Technical Skills:
CUCM-Cisco Unified Communications manger & CUCME-Unified communications express.
Voice Gateways(Cisco 3845 PSTN,VEGA 5000,5024)
BAT-Bulk Administration Tool
Jabber installation with telepresence and troubleshooting.
L1 troubleshooting and configuring CISCO switches.
Telepresence endpoint configuration and troubleshooting DX series, TC software based and CTS
software based endpoints.
Implementing and troubleshooting Translation Rules.
COR-Class of restriction, COS- Class of services
PRI,BRI(E1/T1),CAS,CCS(T1/E1)
Configuring,managing and troubleshooting CISCO gatekeepers.
Configuring troubleshooting of virtual servers on network through VMWARE and VSPHERE
Configuring and troubleshooting over PARATITIONS and CSS-Calling Search Space.
Basic troubleshooting of Cisco UNITY VOICE Mail services.
Configuring various IPT features through CUCM and CUCME Group pickup, Call transfer, call
parking, call forwarding, Intercom, Speed dial, Button templates.
Paging systems Informacast.
UCS B&C series troubleshooting and management.
Routers(7609-VRF,Ethernet ports, Physical connectivity)
Switches(6509-VRF,ARP,Ethernet ports, VLANs Physical connectitvity,3560-VLAN,Ethernet ports,
Physical connectivity )
DSLAM(Configuring and troubleshooting ATRIE 4824-24 ports DSLAM,4800-200 ports DSLAM)
Achievements:
Implemented Voice Over IP lab through Cisco Unified Communication Manager.
Resolved a long pending PSTN caller ID issue/VOIP phone implementation all over the network.
Upgraded FXS and configuration templates of voice gateways installed all over the network within
36 hours.
Implemented 802.1x and upgraded DSLAM all over network for 802.1x authentication.
LAN/WAN Technologies:
Ethernet, Network Bridging through DSLAM’s.
UTM-Unified threat management system.
802.1x authentication server.
Endpoint Hard PBX systems/MDF.
3. Protocol:
SIP,H.323,SCCP,TCP/IP,MGCP,SCCP,TCP,UDP,NAT.
OSPF,CAS,CCS,STP
Implementation of DHCP, FTP, TFTP.
Operating Systems and applications:
Windows 7, Windows 8, 8.1, Windows server 2003, 2008, 2012, Redhat Linux.
VMWARE 6,7,8,9,VSPHERE,Hyper V
Certifications
CCNA collaboration (210-060, 210-065)
Education:
Diploma in Electronics and communication engineering with 83% (Kongu polytechnic college 2013).
Higher secondary 12th Tamilnadu state board.
10th Tamilnadu Matriculation board.
Personal details:
Date of birth: 31-10-1993
Nationality: Indian
Well known Languages: Hindi (understanding and speaking) English & Tamil
Marital status: Unmarried
Declaration:
I hereby, declare that all the information provided in the resume is true to best of my knowledge.
Place: New Delhi
Date: Manojkumar R