This guide provides an overview of Aruba beacon technology, and describes the different types of Aruba beacons, beacon use cases and deployments, as well as predeployment configuration and testing workflows.
This presentation will show how ArubaOS architecture has evolved and been modernized towards the ever growing Virtual Machine world to give mobile workers the best possible experience that is evolving into a key component of the Aruba Mobile First platform. Check out the webinar recording where this presentation was used. https://community.arubanetworks.com/t5/Wireless-Access/Airheads-Technical-Webinar-Recording-Slides-ArubaOS-8-0/m-p/278668
Register for the upcoming webinars: https://community.arubanetworks.com/t5/Training-Certification-Career/EMEA-Airheads-Webinars-Jul-Dec-2017/td-p/271908
SD WAN Overview | What is SD WAN | Benefits of SD WAN Ashutosh Kaushik
Small Brief on Next Generation SD-WAN
Dynamic business landscape and uncompromised demands of applications and users have driven dramatic transformation in IT Networking after many years of relative stability. Frequent changes in technologies are shifting networking from static Infrastructure to more agile, secured, future ready and hybrid-cloud infrastructure. This created un-precedented network management complexities that has become a growing concern for the enterprise.
Early Generation of SD-WAN providers were primarily focused on cost reduction via replacing MPLS with low-cost broadband.
Infinxt Next Generation SD-WAN handles data and network security with in-built NGFW, SLA based Application Performance Enhancement, Traffic Shaping, Multi/ Hybrid Cloud App aware routing, in addition to the traditional SD-WAN features
Infinxt Product Variants
1. Infinxt – Next Generation SD-WAN
Infinxt provides you with the best of the SD-WAN features that can address any of your WAN challenges. The device itself being a Zone based firewall, provides application visibility and control. The decoupled Data Plane and Control plane provides you with the needed flexibility and efficiency in addressing Day 0, Day 1 and Day 2 challenges.
The solution is industry and business agnostic whereby it would be able to meet any type of WAN requirements. The offering being indigenously made would be able to address unique requirements for niche industries too through customization
Features
2. Infinxt - Next Generation Firewall Powered by Palo Alto Networks
Legacy firewall security solutions react to new threats. Intelligent network security stays ahead of attackers and increases business agility. Infinxt SD-WAN comes with a pre-hosted Palo Alto Networks VM in the Infinxt iEdge devices. This offering is a boon for customers to convert their branches into next generation secured branches with the NGFW security capability of Palo Alto Networks.
3. Infinxt - Next Generation Secure SD-WAN Powered by Palo Alto Networks
The Secure Next Generation SD-WAN offering from Infinity Labs provides its customers with the best of both Network connectivity and Application security. It’s a unique combination where both the VMs are service chained to leverage their proficiency to provide a secured application experience to the users. Along with SD-WAN features it also gives NGFW features Powered by Palo Alto Networks.
Infinxt SD-WAN Console gives a Single UI for both SD-WAN and NGFW for ease of Network Operation and Management.
This feature gives the enterprises a unique proposition to have Palo Alto NGFW on tried and tested Infinxt Edge Device.
Palo Alto Networks Advantages
This document summarizes an Aruba Networks presentation on configuring access management with ClearPass. It outlines the agenda which includes reviewing an existing customer deployment, customer challenges and solutions, and a live configuration, authentication, and troubleshooting walkthrough. It then discusses the customer's existing 802.1X deployment and their new initiatives involving mobile device management, a Palo Alto firewall, and a visitor network with ClearPass guest. It explores how ClearPass can help integrate these solutions and limit access to only enrolled devices while applying granular policies. The presentation then demonstrates these concepts in a lab environment.
SD WAN VS MPLS – Which is better for your Business?Phani Kumar
Multiprotocol Label Switching (MPLS) has long been the standard for wide area network before SD-WAN came along. While most professionals consider SD-WAN to be the latest and more effective in enterprise networking problems, the benefits of MPLS technology cannot be ignored. Choosing between these two will depend on your company’s priorities. This guide will explore the two technologies to help you choose the best for your business.
The flagship product of the Aruba Location Services product line is Aruba Beacons. When Aruba Beacons are used in conjunction with the Meridian mobile app platform, they enable public-facing enterprises to infuse their mobile apps with innovative, location-based services.
The purpose of this session is to share leading practices for configuring Aruba OS CX devices in both core and aggregation roles with a focus on collapsed core (two-tier) networks.
The document discusses a case study of MWH Global implementing a software-defined WAN with Cisco and Glue Networks. MWH Global had challenges with provisioning remote sites, operational complexity, and high WAN costs. Using Cisco's software-defined WAN technology and Glue Network's orchestration platform, MWH Global saw benefits like 10-15 times more bandwidth, significant cost savings, and faster deployment of remote sites. The solution provided flexibility, resiliency and automation to simplify their network while reducing costs.
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.
This presentation will show how ArubaOS architecture has evolved and been modernized towards the ever growing Virtual Machine world to give mobile workers the best possible experience that is evolving into a key component of the Aruba Mobile First platform. Check out the webinar recording where this presentation was used. https://community.arubanetworks.com/t5/Wireless-Access/Airheads-Technical-Webinar-Recording-Slides-ArubaOS-8-0/m-p/278668
Register for the upcoming webinars: https://community.arubanetworks.com/t5/Training-Certification-Career/EMEA-Airheads-Webinars-Jul-Dec-2017/td-p/271908
SD WAN Overview | What is SD WAN | Benefits of SD WAN Ashutosh Kaushik
Small Brief on Next Generation SD-WAN
Dynamic business landscape and uncompromised demands of applications and users have driven dramatic transformation in IT Networking after many years of relative stability. Frequent changes in technologies are shifting networking from static Infrastructure to more agile, secured, future ready and hybrid-cloud infrastructure. This created un-precedented network management complexities that has become a growing concern for the enterprise.
Early Generation of SD-WAN providers were primarily focused on cost reduction via replacing MPLS with low-cost broadband.
Infinxt Next Generation SD-WAN handles data and network security with in-built NGFW, SLA based Application Performance Enhancement, Traffic Shaping, Multi/ Hybrid Cloud App aware routing, in addition to the traditional SD-WAN features
Infinxt Product Variants
1. Infinxt – Next Generation SD-WAN
Infinxt provides you with the best of the SD-WAN features that can address any of your WAN challenges. The device itself being a Zone based firewall, provides application visibility and control. The decoupled Data Plane and Control plane provides you with the needed flexibility and efficiency in addressing Day 0, Day 1 and Day 2 challenges.
The solution is industry and business agnostic whereby it would be able to meet any type of WAN requirements. The offering being indigenously made would be able to address unique requirements for niche industries too through customization
Features
2. Infinxt - Next Generation Firewall Powered by Palo Alto Networks
Legacy firewall security solutions react to new threats. Intelligent network security stays ahead of attackers and increases business agility. Infinxt SD-WAN comes with a pre-hosted Palo Alto Networks VM in the Infinxt iEdge devices. This offering is a boon for customers to convert their branches into next generation secured branches with the NGFW security capability of Palo Alto Networks.
3. Infinxt - Next Generation Secure SD-WAN Powered by Palo Alto Networks
The Secure Next Generation SD-WAN offering from Infinity Labs provides its customers with the best of both Network connectivity and Application security. It’s a unique combination where both the VMs are service chained to leverage their proficiency to provide a secured application experience to the users. Along with SD-WAN features it also gives NGFW features Powered by Palo Alto Networks.
Infinxt SD-WAN Console gives a Single UI for both SD-WAN and NGFW for ease of Network Operation and Management.
This feature gives the enterprises a unique proposition to have Palo Alto NGFW on tried and tested Infinxt Edge Device.
Palo Alto Networks Advantages
This document summarizes an Aruba Networks presentation on configuring access management with ClearPass. It outlines the agenda which includes reviewing an existing customer deployment, customer challenges and solutions, and a live configuration, authentication, and troubleshooting walkthrough. It then discusses the customer's existing 802.1X deployment and their new initiatives involving mobile device management, a Palo Alto firewall, and a visitor network with ClearPass guest. It explores how ClearPass can help integrate these solutions and limit access to only enrolled devices while applying granular policies. The presentation then demonstrates these concepts in a lab environment.
SD WAN VS MPLS – Which is better for your Business?Phani Kumar
Multiprotocol Label Switching (MPLS) has long been the standard for wide area network before SD-WAN came along. While most professionals consider SD-WAN to be the latest and more effective in enterprise networking problems, the benefits of MPLS technology cannot be ignored. Choosing between these two will depend on your company’s priorities. This guide will explore the two technologies to help you choose the best for your business.
The flagship product of the Aruba Location Services product line is Aruba Beacons. When Aruba Beacons are used in conjunction with the Meridian mobile app platform, they enable public-facing enterprises to infuse their mobile apps with innovative, location-based services.
The purpose of this session is to share leading practices for configuring Aruba OS CX devices in both core and aggregation roles with a focus on collapsed core (two-tier) networks.
The document discusses a case study of MWH Global implementing a software-defined WAN with Cisco and Glue Networks. MWH Global had challenges with provisioning remote sites, operational complexity, and high WAN costs. Using Cisco's software-defined WAN technology and Glue Network's orchestration platform, MWH Global saw benefits like 10-15 times more bandwidth, significant cost savings, and faster deployment of remote sites. The solution provided flexibility, resiliency and automation to simplify their network while reducing costs.
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.
NetScaler SD-WAN provides software-defined wide area networking and cloud access capabilities that are secure, reliable and ensure high application quality. It offers various editions with standard features including bonding multiple WAN circuits into a single logical circuit, monitoring link conditions, and delivering applications over the best circuit. The product provides centralized configuration and management without requiring branch configurations.
The document outlines an agenda for an Aruba Networks workshop on advanced ClearPass network security. The agenda includes sections on using ClearPass for wired and wireless network access control (NAC), TACACS+ device authentication, and bringing your own device (BYOD) integration using Onboard for certificate provisioning. Monitoring and troubleshooting ClearPass deployments is also discussed.
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
SD WAN simplifies branch office connectivity and management while improving application performance and network visibility. It uses software to direct traffic over multiple connection types, including broadband internet and private links. This allows traffic to automatically switch to the best available connection. SD WAN provides benefits like lower costs, easier management, and application-aware routing compared to traditional router-based WANs. Various vendors offer SD WAN solutions targeting enterprises, communication service providers, or as cloud-based offerings.
The document discusses configuring different APIs in Aruba 8.x. It provides an overview of configuration and context APIs, including REST APIs and NBAPIs. It describes using APIs to get and set configuration parameters via the GUI, CLI, and curl commands. Examples are given of retrieving data via show commands and posting multiple configuration objects at once. The role of the NBAPI helper process in handling location context data is also summarized.
The document provides information about Aruba Mobility Controllers, including:
- It describes the operating model, management, network services, aggregation, and network access functions of the Mobility Controller.
- It introduces the various Mobility Controller models including the 7200, 6000, 3000, and 600 series. The 7200 can support the most devices and tunnels while the 600 is designed for small branch offices.
- It explains the master/local controller hierarchy where one master distributes configuration to local controllers to reduce administrative overhead.
During this presentation, we will cover a deep dive into Aruba Central and its features. Check out the webinar recording where this presentation was used:
https://community.arubanetworks.com/t5/Cloud-Managed-Networks/Technical-Webinar-Advance-Aruba-Central/m-p/496064
This document discusses trends, challenges, and solutions for mobile backhaul networks. It outlines the rapid bandwidth growth requirements for LTE, higher service demands including enterprise services and security, and increased O&M challenges. Huawei's LTEhaul 2.0 solution is presented as addressing these issues through features like proactive O&M, SDN virtualization, seamless multicast, and carrier-grade security. Specific technologies like eMBMS, small cell backhaul, Ethernet demarcation services, and IPSec solutions are also summarized.
EMA’s published software-defined wide-area network (SD-WAN) transformation research, based on a survey of 303 enterprise IT professionals, identifies best practices for modernizing the WAN with SD-WAN and other technology.
These slides from the webinar featuring EMA VP of Research Shamus McGillicuddy
- Give results from EMA’s industry-leading research in enterprise WAN strategies by looking at the dos and don’ts of SD-WAN projects
- Explore emerging requirements for secure access service edge (SASE) solutions
- Examine how the COVID-19 pandemic has affected these networks
The document discusses location analytics and how Aruba's Location Engine (ALE) can provide value to enterprises and public venues through various use cases. It provides an overview of ALE's capabilities like location calculation, geofencing, traffic pattern analysis, and integration with analytics partners. Case studies are presented on using ALE for applications in hospitality, retail, and generating traffic analytics reports. Accurate location data combined with other data sources can improve customer engagement, operational efficiencies, and workspace optimization.
This presentation introduces the motivation behind Beacon Technology and its potential. It briefly provides information about different protocols. The last part of the presentation is about basic implementation details that would enhance the user experience while presenting the current challenges.
This document discusses ClearPass design scenarios for improving the user experience while maintaining security. It addresses allowing employees on the guest network, identifying corporate devices, and supporting "headless" wired and wireless devices that do not support 802.1x authentication. The document recommends using ClearPass policies to communicate with users, provide self-service options, dynamically update other systems, and proactively identify and resolve problems to balance usability and security. It also suggests profiling and registering devices to authorize network access for devices that cannot use 802.1x authentication.
The document provides an overview of Aruba's networking portfolio including their Aruba CX switching portfolio, wireless access points, and network analytics engine. It summarizes the key features of Aruba's switching portfolio including their CX access and aggregation switches ranging from the CX 6100 to CX 8400. It also summarizes Aruba's wireless access point portfolio including their indoor, outdoor, and hospitality APs ranging from entry-level to high-performance 11ac and 11ax models. Finally, it briefly discusses Aruba's network analytics engine and cloud-native architecture.
The document provides useful CLI commands for various functions on an Aruba network including:
- Enabling logging to troubleshoot processes like DHCP or user authentication.
- Checking interface, AP, and radio status and statistics.
- Viewing ARM neighbor reports and scan times.
- Examining user authentication details, roles, and dot1x configuration.
- Checking client connection details, data rates, and troubleshooting high retry counts or errors.
Azure Networking - The First Technical ChallengeAidan Finn
The first "technical" obstacle for many organisations in Azure adoption is often the design of a secure and accessible network or landing zone for workloads and data.
In centralized Aruba WLAN deployments, the mobility controller is the heart of the network. The controller operates as a stand-alone master, or in a master-local cluster. Aruba provides several redundancy models for deploying mobility controllers. Each of these options, including the choice to forgo redundancy, must be understood so that the correct choice can be made for each deployment model.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
Enabling multimedia services on wireless networks is a great idea nowadays, especially given the user demand. But it takes more access points to install, proactive planning for application level performance requirements and multimedia aware RF management functions. Join us to learn about multimedia application behavior and how you can get your wireless network ready.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
Learn how to deploy hundreds of Aruba Beacons, powered by Bluetooth Low Energy (BLE), and manage them centrally or via a mobile app. We'll also discuss how your business partners can take advantage of the Aruba Meridian platform to kick start their mobile engagement efforts and personalize the customer Wi-Fi experience using a custom-branded mobile app and indoor location services.
This document outlines an agenda for a presentation on Microsoft Azure in the enterprise. The agenda includes discussions of Microsoft's cloud strategy, an overview of Azure IaaS and PaaS offerings, Azure storage basics, Azure portals and APIs, Azure resource manager, Azure networking, security mechanisms, traffic management, cloud adoption methodology, Azure security center, and operational analytics. It also lists appendices on Azure stack, service fabric, DevOps, and how Azure is described by Gartner. The presentation aims to provide both a high-level overview and deeper dives into specific Azure services and capabilities.
This document provides guidelines for deploying Microsoft Lync unified communications over an Aruba wireless network. It discusses Lync architecture and features, wireless network design considerations including access point placement and RF planning, quality of service configuration, and troubleshooting tools. The document focuses on using the Lync Software-Defined Networking API and Aruba's network visibility to provide end-to-end monitoring of real-time Lync calls and diagnose performance issues.
The purpose of this guide is to explain the enhancements in 802.11ac standard and provide guidance towards
migrating to 802.11ac with respect to network design, deployment, and configuration best practices for campus environments like offices, university campus, and dorm environments.
This guide covers the following topics in detail:
- Summary of Recommendations
- 802.11ac Features and Benefits
- 802.11ac Planning and Deployment Guidelines
- Best Practice Recommendations for Deploying 802.11ac WLANs
This guide is intended for those who are willing to learn about the 802.11ac standards and understand the best practices in deploying a high-performing 802.11ac
NetScaler SD-WAN provides software-defined wide area networking and cloud access capabilities that are secure, reliable and ensure high application quality. It offers various editions with standard features including bonding multiple WAN circuits into a single logical circuit, monitoring link conditions, and delivering applications over the best circuit. The product provides centralized configuration and management without requiring branch configurations.
The document outlines an agenda for an Aruba Networks workshop on advanced ClearPass network security. The agenda includes sections on using ClearPass for wired and wireless network access control (NAC), TACACS+ device authentication, and bringing your own device (BYOD) integration using Onboard for certificate provisioning. Monitoring and troubleshooting ClearPass deployments is also discussed.
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
SD WAN simplifies branch office connectivity and management while improving application performance and network visibility. It uses software to direct traffic over multiple connection types, including broadband internet and private links. This allows traffic to automatically switch to the best available connection. SD WAN provides benefits like lower costs, easier management, and application-aware routing compared to traditional router-based WANs. Various vendors offer SD WAN solutions targeting enterprises, communication service providers, or as cloud-based offerings.
The document discusses configuring different APIs in Aruba 8.x. It provides an overview of configuration and context APIs, including REST APIs and NBAPIs. It describes using APIs to get and set configuration parameters via the GUI, CLI, and curl commands. Examples are given of retrieving data via show commands and posting multiple configuration objects at once. The role of the NBAPI helper process in handling location context data is also summarized.
The document provides information about Aruba Mobility Controllers, including:
- It describes the operating model, management, network services, aggregation, and network access functions of the Mobility Controller.
- It introduces the various Mobility Controller models including the 7200, 6000, 3000, and 600 series. The 7200 can support the most devices and tunnels while the 600 is designed for small branch offices.
- It explains the master/local controller hierarchy where one master distributes configuration to local controllers to reduce administrative overhead.
During this presentation, we will cover a deep dive into Aruba Central and its features. Check out the webinar recording where this presentation was used:
https://community.arubanetworks.com/t5/Cloud-Managed-Networks/Technical-Webinar-Advance-Aruba-Central/m-p/496064
This document discusses trends, challenges, and solutions for mobile backhaul networks. It outlines the rapid bandwidth growth requirements for LTE, higher service demands including enterprise services and security, and increased O&M challenges. Huawei's LTEhaul 2.0 solution is presented as addressing these issues through features like proactive O&M, SDN virtualization, seamless multicast, and carrier-grade security. Specific technologies like eMBMS, small cell backhaul, Ethernet demarcation services, and IPSec solutions are also summarized.
EMA’s published software-defined wide-area network (SD-WAN) transformation research, based on a survey of 303 enterprise IT professionals, identifies best practices for modernizing the WAN with SD-WAN and other technology.
These slides from the webinar featuring EMA VP of Research Shamus McGillicuddy
- Give results from EMA’s industry-leading research in enterprise WAN strategies by looking at the dos and don’ts of SD-WAN projects
- Explore emerging requirements for secure access service edge (SASE) solutions
- Examine how the COVID-19 pandemic has affected these networks
The document discusses location analytics and how Aruba's Location Engine (ALE) can provide value to enterprises and public venues through various use cases. It provides an overview of ALE's capabilities like location calculation, geofencing, traffic pattern analysis, and integration with analytics partners. Case studies are presented on using ALE for applications in hospitality, retail, and generating traffic analytics reports. Accurate location data combined with other data sources can improve customer engagement, operational efficiencies, and workspace optimization.
This presentation introduces the motivation behind Beacon Technology and its potential. It briefly provides information about different protocols. The last part of the presentation is about basic implementation details that would enhance the user experience while presenting the current challenges.
This document discusses ClearPass design scenarios for improving the user experience while maintaining security. It addresses allowing employees on the guest network, identifying corporate devices, and supporting "headless" wired and wireless devices that do not support 802.1x authentication. The document recommends using ClearPass policies to communicate with users, provide self-service options, dynamically update other systems, and proactively identify and resolve problems to balance usability and security. It also suggests profiling and registering devices to authorize network access for devices that cannot use 802.1x authentication.
The document provides an overview of Aruba's networking portfolio including their Aruba CX switching portfolio, wireless access points, and network analytics engine. It summarizes the key features of Aruba's switching portfolio including their CX access and aggregation switches ranging from the CX 6100 to CX 8400. It also summarizes Aruba's wireless access point portfolio including their indoor, outdoor, and hospitality APs ranging from entry-level to high-performance 11ac and 11ax models. Finally, it briefly discusses Aruba's network analytics engine and cloud-native architecture.
The document provides useful CLI commands for various functions on an Aruba network including:
- Enabling logging to troubleshoot processes like DHCP or user authentication.
- Checking interface, AP, and radio status and statistics.
- Viewing ARM neighbor reports and scan times.
- Examining user authentication details, roles, and dot1x configuration.
- Checking client connection details, data rates, and troubleshooting high retry counts or errors.
Azure Networking - The First Technical ChallengeAidan Finn
The first "technical" obstacle for many organisations in Azure adoption is often the design of a secure and accessible network or landing zone for workloads and data.
In centralized Aruba WLAN deployments, the mobility controller is the heart of the network. The controller operates as a stand-alone master, or in a master-local cluster. Aruba provides several redundancy models for deploying mobility controllers. Each of these options, including the choice to forgo redundancy, must be understood so that the correct choice can be made for each deployment model.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
Enabling multimedia services on wireless networks is a great idea nowadays, especially given the user demand. But it takes more access points to install, proactive planning for application level performance requirements and multimedia aware RF management functions. Join us to learn about multimedia application behavior and how you can get your wireless network ready.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
Learn how to deploy hundreds of Aruba Beacons, powered by Bluetooth Low Energy (BLE), and manage them centrally or via a mobile app. We'll also discuss how your business partners can take advantage of the Aruba Meridian platform to kick start their mobile engagement efforts and personalize the customer Wi-Fi experience using a custom-branded mobile app and indoor location services.
This document outlines an agenda for a presentation on Microsoft Azure in the enterprise. The agenda includes discussions of Microsoft's cloud strategy, an overview of Azure IaaS and PaaS offerings, Azure storage basics, Azure portals and APIs, Azure resource manager, Azure networking, security mechanisms, traffic management, cloud adoption methodology, Azure security center, and operational analytics. It also lists appendices on Azure stack, service fabric, DevOps, and how Azure is described by Gartner. The presentation aims to provide both a high-level overview and deeper dives into specific Azure services and capabilities.
This document provides guidelines for deploying Microsoft Lync unified communications over an Aruba wireless network. It discusses Lync architecture and features, wireless network design considerations including access point placement and RF planning, quality of service configuration, and troubleshooting tools. The document focuses on using the Lync Software-Defined Networking API and Aruba's network visibility to provide end-to-end monitoring of real-time Lync calls and diagnose performance issues.
The purpose of this guide is to explain the enhancements in 802.11ac standard and provide guidance towards
migrating to 802.11ac with respect to network design, deployment, and configuration best practices for campus environments like offices, university campus, and dorm environments.
This guide covers the following topics in detail:
- Summary of Recommendations
- 802.11ac Features and Benefits
- 802.11ac Planning and Deployment Guidelines
- Best Practice Recommendations for Deploying 802.11ac WLANs
This guide is intended for those who are willing to learn about the 802.11ac standards and understand the best practices in deploying a high-performing 802.11ac
This guide covers the deployment of Aruba remote access points (RAP) in fixed telecommuter and micro branch office sites, and it is considered part of the base designs guides within the VRD core technologies series. This guide covers the design recommendations for remote network deployment and it explains the various configurations needed to implement a secure, high-performance virtual branch office (VBN) solution with Aruba RAPs.
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
The document summarizes the setup of an example campus network used to demonstrate an Aruba validated reference design. Key elements include:
- A data center with controllers, AirWave, servers and core switch.
- A distribution layer with two distribution switches connected to two Aruba controllers, with VLANs, VRRP and link aggregation configured.
- The controllers are deployed in an active-active redundant model with VLAN pooling across controllers to support failover.
- Network parameters like VLANs, IPs, DHCP scopes are defined for the controllers and distribution switches.
This guide covers the deployment of Aruba remote access points (RAP) in fixed telecommuter and micro branch office sites, and it is considered part of the base designs guides within the VRD core technologies series. This guide covers the design recommendations for remote network deployment and it explains the various configurations needed to implement a secure, high-performance virtual branch office (VBN) solution with Aruba RAPs.
The document discusses evaluating the network environment, including how the network will be used, determining if the environment has low or high complexity, and considering factors like device usage and applications when planning a wireless network deployment to ensure it meets needs over its lifetime. It also covers selecting the proper access points and antennas and using planning tools like VisualRF Plan to conduct virtual or physical site surveys.
The document discusses evaluating the network environment, including how the network will be used and determining if it is a low or high-complexity environment. It also covers selecting the appropriate Aruba access points and antennas based on the environment evaluation and planning the network layout either virtually using VisualRF Plan or with a physical site survey.
This guide details the advanced guest access features available to organizations through the combination of Aruba’s Amigopod and Mobility Controller solutions. This includes details of workflow management, RADIUS configuration, AAA configuration, and testing of the solution. This guide builds on the network defined in the Campus VRD.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
The document discusses Aruba's mobile engagement solutions for enterprises, including its Meridian mobile app platform and use of Bluetooth beacons. Key points include that the platform allows for easy updating of app and map content, works across iOS and Android, provides single login access, utilizes ClearPass Guest and push notifications for engagement, and includes wayfinding, search and indoor positioning features. It also offers options for integrating with or creating custom branded apps using the Meridian SDK and platform.
AltBeacon: The Open and Interoperable Beacon SpecificationDavid Helms
Because there is no open and interoperable specification for proximity beacons, Radius Networks has authored the AltBeacon specification as a proposal for how to solve this problem.
This presentation reviews the details of the AltBeacon spec, why it has been developed as a completely open beacon specification and how you can get involved in furthering the evolution of AltBeacon.
The document discusses Aruba's mobile engagement solutions including making Wi-Fi and Bluetooth work together, indoor mapping and wayfinding using real-time location services, proximity-based mobile notifications, and their Meridian software development kits and app platform. It also describes Aruba beacons which provide location services and push notifications using Bluetooth low energy, and how Aruba Wi-Fi infrastructure helps manage the beacons and provides comprehensive monitoring and management tools.
As part of its mobile engagement solution, Aruba offers all mobile app developers the opportunity to take advantage of Aruba Beacons and Aruba Meridian SDK to create engaging experiences within a venue's existing mobile app. Join us for a discussion of best practices on how you can engage with internal or external mobile app developers.
This document provides a validated reference design for deploying an Aruba campus wireless network. It describes recommendations for the network design, including using a cluster-based architecture with redundancy between master and local mobility controllers. It also covers configuring different types of AP groups for client access and air monitors. The design establishes separate wireless networks (SSIDs) for employees, applications, and guests, with each having customized access policies and security. This validated design provides a proven approach for implementing a secure, high-performance wireless LAN in a large campus environment.
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 guide focuses on configuration of DHCP fingerprinting, which is used in conjunction with user roles on the Aruba Mobility Controller. When a user authenticates, their device type is taken into account. Based on that device type, a new role can be assigned to the device, such as restricting access to certain protocols or completely blocking access.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
Building Proximity-Aware Apps with Beacons - MODEV IOT + Wearables 2014David Helms
This document discusses how beacons and proximity-aware mobile apps work together. Beacons are Bluetooth transmitters that can uniquely identify and determine the proximity of nearby mobile devices. Proximity-aware mobile apps can detect when a mobile device enters or exits the signal range of a beacon and present location-based content. Examples are provided of how beacons could be used in retail stores, museums, hospitals, and other locations to enhance user experiences through proximity-aware mobile apps.
The document describes Aruba mobility controllers, including:
- The 7200, 6000, 3000, and 600 series controllers that scale from small branch offices to large campuses.
- Mobility controllers operate at the network services and aggregation layers, providing functions like user authentication, guest access, RF optimization, and traffic forwarding.
- The master/local controller model allows one master controller to manage multiple local controllers to reduce administrative overhead.
- Licenses determine the functionality and capacity of mobility controllers.
Stop freakin it's just a beacon seattle tech forumJames Senior
This document discusses beacon technology and its uses. It provides an overview of how beacons work using Bluetooth to send unique IDs to nearby devices. This allows for targeted content delivery and location-based applications. The document also outlines common beacon use cases in marketing, tracking, and vertical industries. It describes the components of the beacon ecosystem including hardware manufacturers, cloud services, and OS support and integration required for beacon apps.
Cubeacon Smart Retail Industry with iBeacon TechnologyAvianto Tiyo
In today's modern era, million people have smartphone. High mobility makes em feel hungry for e facilities and conveniences.
Mobile application is what people need most ese days. It can access web from eir mobile device and facilitate eir daily activities. Their expectations for more relevant information will continue to evolve. Not much of developers who finally success. No matter how beautifully designed, todays app must be combined wi a 'powerful tool' to connect directly to e customer for more effective connectivity.
Consumers no longer want to rely on emails and expect eir apps to notify em e moment relevant events occur, and not a second later.
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.
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
The document introduces Eddystone, an open Bluetooth low energy (BLE) beacon format developed by Google. It discusses how Eddystone aims to address real-life use cases, support multiple platforms, and ensure security and privacy. It also describes the various Eddystone frame types and how the format supports better context for apps and easier management of beacon fleets for businesses. Finally, it provides examples of how Google products will utilize Eddystone beacons.
A telecommunications company wanted to streamline their fiber optic network testing process using mobile devices. A Xamarin-based cross-platform native mobile application was developed to allow 2,000 technicians to conduct over 100,000 fiber optic tests in real-time. The application integrated with cloud services and Bluetooth hardware to transfer test results seamlessly from the field to remote engineers for analysis and troubleshooting. This helped the client significantly reduce the time required to detect and resolve network issues.
Cubeacon iBeacon Platform and BackEnd as a ServiceAvianto Tiyo
Cubeacon is a wireless beacon device and platform that allows developers to create location-based mobile applications. The small cubeacon devices broadcast Bluetooth signals to nearby smartphones to precisely locate them. The integrated cloud-based software allows users to set scenarios, manage campaigns, and analyze user behavior and location data. Cubeacon offers a complete solution for developers to easily build interactive mobile apps connected to physical locations.
This guide provides a description of the various bandwidth reservation and quality of service (QoS) options for supporting voice traffic in an Aruba remote access point (RAP) telecommuter deployment scenario. The RAP solution is a key component of the Aruba virtual branch network (VBN) architecture. The Aruba RAP deployment model meets the needs of fixed telecommuter and small branch office deployments while maintaining simplicity and ease of deployment. Aruba RAPs extend the corporate LAN to any remote location by enabling seamless wired or wireless data and voice wherever a user finds an Internet-enabled Ethernet port or 3G cellular connection. RAPs are ideally suited for small remote offices, home offices, telecommuters, mobile executives, and for business continuity applications.
To learn more, visit us at http://www.arubanetworks.com/wlan. Join the discussion at https://community.arubanetworks.com
Similar to Aruba Beacons Validated Reference Guide (20)
Aruba Central user may need a centralized web-server to host captive portal page for their distributed networks across the globe like coffee shops, restaurant or hotels. Aruba central 2.0 has a new feature called Cloud Guest or Guest Management that allows administrator to create a splash page for guest users using Web server and radius server running in the cloud.
Check out the webinar recording where this presentation was used:
https://community.arubanetworks.com/t5/Cloud-Managed-Networks/Airheads-Tech-Talks-Cloud-Guest-SSID-on-Aruba-Central/td-p/524320
ClearPass OnGuard agents perform endpoint posture assessment and ensure that compliance is met before granting access to the network. This session will cover the ClearPass OnGuard Agent components and work-flow in detail.
Check out the webinar recording where this presentation was used:
https://community.arubanetworks.com/t5/Security/Airheads-Tech-Talks-Understanding-ClearPass-OnGuard-Agents/td-p/524288
Clustering is a new feature introduced in AOS 8.0 that enables seamless roaming of clients between APs, hitless client failover and load balancing of users across Mobility Controllers in the cluster. This solution provides the configuration required to create a cluster of Mobility Controllers that are managed by the same Mobility Master.
Check out the webinar recording where this presentation was used:
https://community.arubanetworks.com/t5/Wired-Intelligent-Edge-Campus/Airheads-Tech-Talks-Advanced-Clustering-in-AOS-8-x/td-p/506441
During this webinar, we will cover AppRF - a suite of application visibility and control features that are part of Aruba's Policy Enforcement Firewall. AppRF is a PEF feature that is designed to give network administrators insight into the applications that are running on their network, and who is using them. Check out the webinar recording where this presentation was used:
https://community.arubanetworks.com/t5/Wireless-Access/Technical-Webinar-Aruba-AppRF-AOS-6-x-amp-8-x/td-p/490800
This document discusses ArubaOS switch stacking, including:
- Backplane stacking allows connecting multiple switches together to simplify operations and optimize uplink usage.
- Topologies supported are chain, ring, and mesh, with ring and mesh recommended for redundancy.
- Key functions of stacking include topology discovery, electing a commander and standby, managing members, and handling splits.
- Specific switch models like the 3800 and 2900 series support backplane stacking of up to 10 units in ring topology with stacking throughput of up to 160Gbps.
In this presentation, we will discuss how IEEE standard 802.3ad and its implications allow third-party devices such as switches, servers, or any other networking device that supports trunking to interoperate with the distributed trunking switches (DTSs) seamlessly. Check out the webinar recording where this presentation was used: http://community.arubanetworks.com/t5/Wired-Intelligent-Edge-Campus/Technical-Webinar-LACP-and-distributed-LACP-ArubaOS-Switch/td-p/458170
Register for the upcoming webinars: https://community.arubanetworks.com/t5/Training-Certification-Career/EMEA-Airheads-Webinars-Jul-Dec-2017/td-p/271908
In this presentation, e will discuss AirWave 10, a new software build that lets us streamline code, add performance, clustering. Check out the webinar recording where this presentation was used: http://community.arubanetworks.com/t5/Network-Management/Technical-Webinar-Introduction-to-AirWave-10/td-p/454762
Register for the upcoming webinars: https://community.arubanetworks.com/t5/Training-Certification-Career/EMEA-Airheads-Webinars-Jul-Dec-2017/td-p/271908
In this presentation, we will discuss how Virtual Switching Framework (VSF) allows supported switches connected to each other through Ethernet connections (copper or fibre) to behave like a single chassis switch. Check out the webinar recording where this presentation was used: http://community.arubanetworks.com/t5/Controllerless-Networks/Technical-Webinar-Virtual-Switching-Framework-ArubaOS-Switch/td-p/445696
Register for the upcoming webinars: https://community.arubanetworks.com/t5/Training-Certification-Career/EMEA-Airheads-Webinars-Jul-Dec-2017/td-p/271908
In this presentation, we will cover the Central platform which provides a standard Web-based interface that allows you to configure and monitor multiple Aruba Instant networks / Switches from anywhere with a connection to the Internet. Check out the webinar recording where this presentation was used: http://community.arubanetworks.com/t5/Cloud-Managed-Networks/Technical-Webinar-Aruba-Central-with-Instant-AP/td-p/429366
Register for the upcoming webinars: https://community.arubanetworks.com/t5/Training-Certification-Career/EMEA-Airheads-Webinars-Jul-Dec-2017/td-p/271908
In this presentation, we will discuss how AirGroup configurations have changed to support hierarchical configuration in release 8.2. AirGroup configs will now be profile based and can be applied at any node. Check out the webinar recording where this presentation was used: http://community.arubanetworks.com/t5/Wireless-Access/Technical-Webinar-AirGroup-profiling-changes-across-8-1-amp-8-2/td-p/417153
Register for the upcoming webinars: https://community.arubanetworks.com/t5/Training-Certification-Career/EMEA-Airheads-Webinars-Jul-Dec-2017/td-p/271908
In this presentation, we will explore the RESTApi as the ClearPass API integrations and further developments are more focused to RESTApi than the other existing API services like xml-rpc, SOAP, etc.Check out the webinar recording where this presentation was used: http://community.arubanetworks.com/t5/Security/Technical-Webinar-Getting-Started-with-the-ClearPass-REST-API/td-p/410214
Register for the upcoming webinars: https://community.arubanetworks.com/t5/Training-Certification-Career/EMEA-Airheads-Webinars-Jul-Dec-2017/td-p/271908
During this webinar, we will discuss how starting from ArubaOS 8.2.0.0, selected APs can run in both controller-based mode and controller-less mode and the implications tied to that. Check out the webinar recording where this presentation was used: http://community.arubanetworks.com/t5/Wireless-Access/Technical-Webinar-AP-Discovery-amp-Deployment-Policy-ArubaOS-8-x/m-p/394540/
Register for the upcoming webinars: https://community.arubanetworks.com/t5/Training-Certification-Career/EMEA-Airheads-Webinars-Jul-Dec-2017/td-p/271908
In this presentation, we will discuss the L3 Redundancy Requirement which primarily comes from customers who want to handle the complete Data Center Failure during natural disasters or other catastrophic events. Check out the webinar recording where this presentation was used: http://community.arubanetworks.com/t5/Wireless-Access/Technical-Webinar-Layer-3-Redundancy-for-Mobility-Master-ArubaOS/td-p/382029
Register for the upcoming webinars: https://community.arubanetworks.com/t5/Training-Certification-Career/EMEA-Airheads-Webinars-Jul-Dec-2017/td-p/271908
This document discusses managed device deployment at branch offices using Aruba branch controllers. It provides an overview of how branch controllers connect to a master controller via an internet modem and establish communication. It also covers branch controller and VPN concentrator configuration in Aruba OS versions 6.x and 8.x, including initial setup, zero touch provisioning, and debugging tools. Additional topics include address pool management for VLANs, tunnels, NAT, and DHCP to allow for dynamic IP assignment at branch office deployments.
The existing channel and power assignment functions in ARM support channel scanning, channel assignment and power adjustments, locally. Decisions are made locally at the AP without looking at the entire network. Thanks to the dynamic machine learning techniques, AirMatch centralises this function in the Mobility Master while dynamically learning the network and adapting the RF planning for the entire network. Check out the webinar recording where this presentation was used: http://community.arubanetworks.com/t5/Wireless-Access/Technical-Webinar-Recording-Slides-What-does-AirMatch-do/td-p/314413
This document provides an overview and introduction to the Aruba 8400 switch, which is designed for campus core and aggregation applications. It describes the hardware architecture including line cards, management modules, fabric modules, and power supplies. It also discusses the software architecture of ArubaOS-CX running on the 8400 and its high availability, programmability, security, and analytics capabilities. Example deployments of the 8400 as a campus core and aggregation solution are shown.
These slides were used during our Airheads Meetup Event at Jaarbeurs Utrecht on October 27th 2017.
If you have ideas, new speaker topics and recommendations for the events, please help us to improve for next year’s event by commenting on the community page: http://community.arubanetworks.com/t5/Wireless-Access/Airheads-Technical-Event-The-Netherlands-October-27th-2017/m-p/313566#M75870
These slides were used during our Airheads Meetup Event at Jaarbeurs Utrecht on October 27th 2017.
If you have ideas, new speaker topics and recommendations for the events, please help us to improve for next year’s event by commenting on the community page: http://community.arubanetworks.com/t5/Wireless-Access/Airheads-Technical-Event-The-Netherlands-October-27th-2017/m-p/313566#M75870
These slides were used during our Airheads Meetup Event at Jaarbeurs Utrecht on October 27th 2017.
If you have ideas, new speaker topics and recommendations for the events, please help us to improve for next year’s event by commenting on the community page: http://community.arubanetworks.com/t5/Wireless-Access/Airheads-Technical-Event-The-Netherlands-October-27th-2017/m-p/313566#M75870
In this presentation, we will be debugging Aruba RAP commands, run through troubleshooting and logs and tackle RAP clusters.
Check out the webinar recording where this presentation was used: http://community.arubanetworks.com/t5/Wireless-Access/Technical-Webinar-Recording-Slides-Aruba-Remote-Access-Point-RAP/td-p/310448
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3. Aruba Beacons | Validated Reference Design Contents | 3
Contents
Contents 3
Preface 5
Validated Reference Design Overview 5
About This Document 5
Additional Reference Material 5
Introduction to Aruba Beacons 6
Mobile Engagement with Aruba Networks 6
Beacon-Compatible Devices 7
Aruba Beacon Types 8
Beacon Configuration Modes 9
Aruba Beacon Placement Models 11
Path Model 11
Area Model 12
Deployment Considerations 12
Atrium Deployments 13
Predeployment Planning 16
Hardware and Software Requirements 16
Beacon IDs 16
Beacon Power Levels 17
Deploying and Configuring Beacons 18
Install the Beacons App 18
Add a New Beacon 18
View Beacon Signal Strength and Density 20
Beacon Management 22
Beacon Management Workflow 22
4. 4 | Contents Aruba Beacons | Validated Reference Design
Beacon Management Considerations 22
Managing Campaigns 23
Before you Begin 23
Monitoring and Managing Beacons with Meridian 27
Troubleshooting 28
Configuring and Testing Campaigns 30
Creating a Campaign 30
Testing a Campaign 31
Transmission Power Levels 33
5. Aruba Beacons | Validated Reference Design Preface | 5
Preface
Validated Reference Design Overview
The Aruba Validated Reference Design (VRD) series is a collection of technology deployment guides that include
descriptions of Aruba technology, recommendations for product selections, network design decisions,
configuration procedures, and best practices for deployment. Together these guides comprise a reference
model for understanding Aruba technology and designs for common customer deployment scenarios. Each
Aruba VRD network design has been constructed in a lab environment and thoroughly tested by Aruba
engineers. Our customers use these proven designs to rapidly deploy Aruba solutions in production with the
assurance that they will perform and scale as expected.
About This Document
This VRD describes Aruba beacons, small, low-power wireless transmitters that broadcast Bluetooth Low-
Energy (BLE) signals that can be heard and interpreted by iOS and Android devices. Aruba beacons integrate
with Meridian-powered apps for more granular mobile engagement, such as providing directions with a glowing
blue dot or sending push-notifications based on a visitor’s real-time location.
This guide provides an overview of Aruba beacon technology, and describes the different types of Aruba
beacons, beacon use cases and deployments, as well as predeployment configuration and testing workflows.
Additional Reference Material
This guide helps a wireless engineer deploy and configure Aruba beacons in a path or area model deployment.
It is a base design guide for Aruba beacons and therefore it will not cover the fundamental wireless concepts.
Readers should have a good understanding of wireless concepts and the Aruba technology.
For more information on Aruba beacons, refer to the following documents, available for download from the
Aruba Networks website:
l Aruba Location Services datasheet
l Mobile Engagement Solution Overview
l Aruba LS-BT1 Location Beacon Installation Guide
For more information on the Meridian mobile app platform, refer to the Meridian documentation set at
http://docs.meridianapps.com/help/intro_meridian.
6. Aruba Beacons | Validated Reference Design Introduction to Aruba Beacons | 6
Chapter 1
Introduction to Aruba Beacons
Mobile Engagement with Aruba Networks
Aruba beacons are small, low-power wireless transmitters that broadcast Bluetooth Low-Energy (BLE) signals
that can be heard and interpreted by iOS and Android devices that have Bluetooth enabled. Aruba beacons
offer increased reliability and accuracy of indoor positioning for apps created with Meridian’s AppMaker and
SDKs. When you use Aruba beacons in conjunction with the Meridian mobile app platform, the beacons allow
public-facing enterprises like large retail spaces, hospitals, hotels, stadiums, museums, schools and airports to
infuse their mobile apps with innovative, location-based services.
The Meridian Mobile App Platform
When a mobile device with a Meridian-powered mobile app is within range of Aruba beacons, guests using that
app can receive personalized, proximity-aware push notifications, and view a glowing blue dot that shows their
real-time location on a venue’s map.
The Meridian mobile app platform includes the following features:
l Meridian Editor: A cloud-based content management system that serves as the online hub for Meridian-
powered tools. Beacons are monitored and managed through the Meridian Editor.
l AppMaker: A module in the Meridian Editor that lets you build a mobile app for your venue. Beacons can
work in conjunction with a Meridian-powered app to provide customers using that app with push
notification and location services.
l Mapping and self-guided wayfinding : This Meridian feature lets venues use data from Aruba beacons to
incorporate location- specific mapping and turn-by-turn directions into their Meridian-powered mobile app.
You can order a customized (white-label) iOS and Android app from Meridian, create your own app using the
Meridian SDK tools, or use the SDK tools to add mapping and wayfinding (NavKit), indoor positioning on a map
(BluDotKit), and proximity-based notifications (ZoneKit) to an existing app built by a third-party developer.
Integration with ClearPass Guest
Aruba Networks' ClearPass Guest is a scalable, easy-to-use visitor management solution that delivers secure
guest access for customers, contractors, and partners using any type of mobile device. If your network
deployment includes ClearPass Guest, a customized ClearPass Guest login portal prompts customers and
guests to download your custom-branded Meridian mobile app after logging in to your network. Note,
however, that ClearPass is not required for a beacon deployment.
Integration with Aruba Wi-Fi
Communication between the beacons and the client devices is not dependent upon an active Wi-Fi connection.
However, you may choose to integrate your beacon deployment with an Aruba Wi-Fi network to simplify
beacon management.
Beacons also work in a non-Aruba wireless network, although deploying them in an Aruba WLAN allows you to
benefit from the beacon management capabilities that the combination of Meridian and Aruba APs provide.
Beacons that are user-installed or factory-installed into an Aruba AP can monitor other Aruba Beacons within
range and send relevant management data back to the Meridian Editor. This allows you to efficiently manage
7. 7 | Introduction to Aruba Beacons Aruba Beacons | Validated Reference Design
the content on your Meridian-powered mobile apps as well as Aruba Beacons from one user-friendly, cloud-
based location. Edits made to the Meridian Editor are instantly applied to Aruba Beacons in your venue.
The following graphic shows how beacons, the Meridian app, and the optional integration with Aruba Wi-Fi and
ClearPass software work together in an coordinated solution. ClearPass Guest allows visitors to log in to your
Aruba Wi-Fi network, register with your enterprise, then download your customized, Meridian-powered mobile
app. The Aruba beacons deployed at your site send signals to your customers' iBeacon-compatible mobile
devices, which are used by the Meridian mobile app to identify the device's location. The mobile app provides
real-time wayfinding and generates push notifications based on instructions from your cloud-based Meridian
account.
Figure 1 Integrating Aruba Wi-Fi and ClearPass Guest into a Beacon Deployment
Beacon-Compatible Devices
Aruba beacons support the iBeacon standard, an Apple protocol supported by Bluetooth-enabled smart
devices, including mobile devices running iOS 7 or later, or Android devices that support Bluetooth 4.0. An
Aruba beacon transmits a unique identifier that can be detected by beacon-compatible smart devices in its
area. When smart devices are in close proximity to an Aruba beacon, software on these devices can perform
actions based on the beacon identifier, such as show the location of the device on a floor map, or trigger push
notifications about nearby items for sale.
8. Aruba beacons do not send push notifications directly to devices, just information about the beacon identity. The
Meridian-powered app sends push notification directly to devices, based upon instructions it receives from your
Meridian account.
A smart device running a Meridian-powered app can use Aruba beacons to pinpoint the location of visitors with
a high level of accuracy. Optimal deployments allow smart devices to identify their locations within less than
three meters. Communication between the beacons and the client devices is not dependent upon an active Wi-
Fi connection, although the client must have Bluetooth enabled. These low-latency communications have a
delay of less than two-seconds, providing accurate and timely wayfinding for clients devices, as well as highly
targeted push notifications.
Aruba Beacon Types
Aruba offers the following different types of beacons:
l Battery-Powered Beacons: The standalone battery-powered beacon can be mounted using an adhesive
sticker, an indoor mounting bracket, or an outdoor enclosure box.
l USB-Powered Beacons: The smaller USB-powered beacon can be inserted into the USB port of an Aruba
access point or any other device with an available USB port. Note that plugging a USB beacon into a
supported Aruba AP adds beacon management capabilities. The battery-powered beacon can
communicate only with iBeacon-compatible devices and beacons in an Aruba AP. A USB-powered beacon
in an AP communicates with clients and battery-powered beacons, but can also send information about the
beacon's status, battery level, power level and firmware to the Aruba controller and Meridian Editor.
l Beacons in APs: AP-320 series access points include a built-in beacon that operates in a manner similar to
a USB-powered beacon, in that the beacon built in to the AP communicates with clients and battery-
powered beacons, but can also send information about the beacon's status, battery level, power level and
firmware to the Aruba controller and Meridian Editor.
Figure 2 An Aruba USB Beacon and Battery-powered beacon
As shown in Figure 3 below, an enterprise customer can view and configure Aruba beacon settings from within
the Meridian Editor. Meridian pushes configuration changes down through the Aruba controller to beacons
installed into an AP USB port or built in to an AP-320 series AP. The beacon in the AP then sends this
information directly to the battery-powered beacons on the network.
Aruba Beacons | Validated Reference Design Introduction to Aruba Beacons | 8
9. 9 | Introduction to Aruba Beacons Aruba Beacons | Validated Reference Design
Figure 3 Beacon Management Topology
Beacon Configuration Modes
Aruba beacons can be deployed in one of two modes, as a location beacon or a proximity beacon.
l Location beacons support location-based wayfinding using a Meridan app. Beacons deployed in this
mode can show mobile app users their indoor location with a glowing blue dot, allowing the users to search
for and locate nearby products and services. You can fully configure location beacons using only the
Beacons app.
l Proximity beacons allow a Meridian app to send push notifications to mobile devices that come within
signal range of that beacon. Proximity beacons are also configured using the Aruba Beacons app, but you
must use the Meridian editor to define and manage push notifications for those devices. For more
information on defining push notification campaigns for location beacons, see Configuring and Testing
Campaigns on page 30.
The first image in the figure below shows an example of blue-dot wayfinding using location beacons and a
Meridian-powered app. The second image shows a push notification that is triggered when a customer using a
Meridian app comes within range of a proximity beacon. In this second image, the campaign notifies customers
using a Meridian-powered app about a sale on shoes when the user enters the shoe department.
Figure 4 Pathfinding and Push Notifications using a Meridian-powered App
11. Aruba Beacons | Validated Reference Design Aruba Beacon Placement Models | 11
Chapter 2
Aruba Beacon Placement Models
The layout of your floor and the type of location tracking required determines the type of deployment used in
a particular venue. There is no single deployment design that is perfectly suitable for every environment, but
there are two primary models for deploying Aruba Beacons; a path model, and an area model.
l Path model: applicable in settings where straight line location accuracy is required. This model is suitable
for blue dot tracking in areas such as narrow hallways or corridors.
l Area model: best used in larger areas such as wide rooms or hallways. An area model deployment is
applicable for settings where two-dimensional location accuracy is required.
For a list of other factors to consider while deploying beacons, refer to Deployment Considerations on page 12.
Path Model
In the example shown in Figure 5, the beacons are ceiling-mounted in a narrow corridor between two meeting
rooms. As the client device (represented by the smart phone icon) moves through the corridor, the blue dot
moves in a straight line following the beacons. The blue dot will move in a straight line regardless of the client
device's actual position in the corridor.
Figure 5 Path Model
12. 12 | Aruba Beacon Placement Models Aruba Beacons | Validated Reference Design
Area Model
The example illustrated in Figure 6 shows six ceiling-mounted beacons installed in a wide hallway. As the client
device moves throughout the corridor, the blue dot follows the client along both the x-axis and y-axis. Since
this deployment allows for two-dimensional location tracking, the blue dot displays the client's actual location.
If ceiling-mounting is not a feasible option, you can achieve similar two-dimensional location accuracy by wall-
mounting beacons in a zig-zag fashion across the hallway .
Figure 6 Area Model
Deployment Considerations
Before installing Aruba Beacons, consider the items described in the following sections. The following factors
should be considered when determining the placement of beacons to ensure the performance required by
your deployment.
Beacon Sizing
For better location accuracy, ensure that successive beacons are placed no more than 40 feet apart. Closer
beacon placement provides the best indoor positioning experience by reducing blue dot jumpiness. However,
the optimal distance between beacons may vary based on factors such as the deployment model, variations in
ceiling height, reflective vs. non- reflective environments, etc.
The no-more-than-40-feet statement is a guideline and your actual deployment may differ. For example, a
smaller distance between beacons may be needed to provide tighter location accuracy. However, in larger open
areas, a wider spread of beacons might be sufficient.
Beacon Mounting
Battery-powered beacons have multiple mounting options and techniques. The two most common mounting
techniques are wall mounting and ceiling mounting. Three mounting options are available for battery-powered
beacons:
l Adhesive on the back of the beacon
l Indoor mounting bracket (useful for replacing beacons in the future)
l Outdoor mounting enclosure
13. The options and techniques used in your deployment will depend on the factors described in the following
sections.
Wall Mounting
Wall mounting can be used in open-roof areas or areas with very high ceilings where installation might be a
challenge. Wall mounting is easier than ceiling mounting and all three mounting options are useable. However,
the beacons are more conspicuous.
Ceiling Mounting
Ceiling mounting is ideal for environments with aesthetics concerns, since it allows beacons to be installed
discreetly and out of line of sight. Additionally, ceiling mounting keeps beacons out of reach from curious
people and prevents tampering. Since the beacons are placed above the tracked devices, ceiling mounting
provides more resiliency to attenuation from crowds.
Keep the following in mind when installing ceiling-mounted beacons:
l Ensure that beacons are mounted far enough from heat generated by light bulbs.
l Beacons must be mounted below ceiling tiles, as some types of tiles may impair beacon signal transmission
if the beacons are mounted above the tiles.
l Ensure that the beacon's power level is high enough for the client app to hear and configure the beacon
when necessary. NOTE: Only proximity beacons power levels can be adjusted.
l For environments with different ceiling heights, ensure that beacons are placed on the lower ceiling height
to prevent the blocking of beacon signal from different locations.
l Ceiling mounting may require a personnel lift or mounting stick. Take proper safety precautions when
using such equipment.
Reflective Environments
Reflective environments, such as areas with marble floors, may result in jumpiness of the blue dot. Carpeted
areas have shown better blue dot stability than areas with marble floors. In locations where reflective surfaces
are unavoidable, consider using the path model instead of the area model.
Atrium Deployments
Due to beacon signal bleed, deploying beacons in environments such as mall with an open atrium requires
proper planning. Without proper planning, blue dot location tracking may be inaccurate and may even report
the blue dot on the wrong floor. As seen in Figure 7, the client device receives a signal from beacons on multiple
floors.
Aruba Beacons | Validated Reference Design Aruba Beacon Placement Models | 13
14. 14 | Aruba Beacon Placement Models Aruba Beacons | Validated Reference Design
Figure 7 Atrium Deployment -Side View
Beacon Placement
Although places like malls are often made up of walkways and corridors, the path model is not recommended.
Installing beacons in the center of a ceiling, using the path model, would typically work in a corridor. However,
in an atrium with open air between floors, the beacon signal can bleed down to lower floors. This results in blue
dot appearing on the wrong floor.
Using the area model provides better blue dot location accuracy. The best blue dot experience is found when
beacons are placed closer to the ground (less than or equal to three feet) and facing upwards, reducing signal
bleed to the lower floors.
Figure 8 Atrium Deployment - Beacon Placement
Securing Beacons
Placing beacons on or close to the floor may not be secure or realistic but some measures can be taken to keep
beacons out of the reach of people.
Consider the example shown in Figure 8. In this deployment, the beacons could be placed on the opposite side
of the glass to prevent tampering. The beacons could be placed on the outside of the glass railing or inside the
shop's window. Keep in mind that the thickness of the glass might attenuate the beacon's signal but the power
level can be adjusted for proximity beacons.
16. Aruba Beacons | Validated Reference Design Predeployment Planning | 16
Chapter 32
Predeployment Planning
Hardware and Software Requirements
Aruba Networks offers three types of beacons, a battery-powered beacon, a USB-powered beacon, and the
beacon built in to an AP-320 series AP. The hardware and software configuration requirements vary between
these different model types.
Battery-Powered Beacons
Before you begin to configure a battery-powered beacon, you'll need the following items:
l One or more Aruba battery-powered beacons.
l An iBeacon-compatible mobile device running iOS 7 or later with Wi-Fi or 3G/4G internet connectivity, such
as an iPhone 4S or later, iPod touch 5 or later, or iPad 3 or later.
l The Aruba Beacons app installed on the iOS mobile device.
l An active Meridian Editor account configured with floor maps of your deployment site.
Log in to the Beacons app using your Meridian Editor credentials. To configure these devices as location
beacons, your Meridian account only needs to be configured with floor maps of each deployment site. To
configure proximity beacons and send push notifications, you must also define a push notification campaign in
the Meridian Editor. For more information, see Configuring and Testing Campaigns on page 30.
USB-Powered Beacons and Beacons in an AP-320 Series Access Point
A beacon connected to the USB port of an Aruba AP or built into an AP-320 series AP communicates with
battery-powered beacons in the area, then sends information about those beacons through the Aruba
controller to the Meridian editor in the cloud.
USB-powered beacons are supported by AP-220 series, AP-210 series and later model access points associated
with a 7200 Series or 7000 Series controller running ArubaOS 6.4.3.2 or later. If the AP uses PoE, ensure it is
using 802.3at, as the USB port will be disabled on 802.3af.
To use the beacon within an AP-320 series AP, that AP must be associated with a 7200 Series or 7000
Series controller running ArubaOS 6.4.4.0 or later .
To configure a USB-powered beacon or a beacon in an AP-320 series AP to communicate with battery-powered
beacons, you'll need the following items:
l An iBeacon-compatible mobile device running iOS 7 or later with Wi-Fi or 3G/4G internet connectivity, such
as an iPhone 4S or later, iPod touch 5 or later, or iPad 3 or later.
l The Aruba Beacons app version 2.1.1 or later, installed on the iOS mobile device.
l An active Meridian Editor account configured with floor maps of your deployment site.
l One or more Aruba battery-powered beacons running version 1.1-4 or later.
Beacon IDs
Every Aruba beacon is identified by a name and a unique MAC address. When you configure a beacon, the
Beacons app also assigns a unique identifier to each beacon comprised of a Universal Unique Identifier (UUID),
and major and minor values. A UUID contains 32 Hexadecimal digits, and major and minor values are integers
between 1 and 65535 used to better identify the devices within your organization.
17. 17 | Predeployment Planning Aruba Beacons | Validated Reference Design
The Meridian editor allows you to edit the name of a beacon, but the preset UUID, major and minor values
cannot be changed.
The iBeacon advertisement messages transmitted by Aruba beacons are sent in a specific format defined by
Apple, and include data about the beacon UUID, major and minor values. Figure 10 below describes the format
of an iBeacon advertisement packet.
Figure 10 iBeacon Frame Data Components
Beacon Power Levels
The Beacons app allows you to deploy a proximity beacon at the power level that best suits your deployment
needs and environment. By default, a proximity beacon sends signals at a Level 14 signal strength (0 dBm).
Informal testing shows that in open-air environments with minimal interference, a proximity beacon
transmitting at this default power level can be detected with an RSSI of -94 dBm by a client mobile device 25
meters away.
For more information on signal strength from beacons at different power levels and the perceived signal power seen
by clients at varying distances from the beacon, see Appendix A: Transmission Power Levels.
If you want your proximity beacon to be heard within a larger area, or your environment contains elements like
walls or doors that can limit a bluetooth signal, consider increasing the signal strength to a higher level.
Similarly, if you want to limit push notifications to within a smaller radius of your beacon, you can reduce the
signal strength, so a client mobile device must be closer to the beacon to hear the bluetooth signal.
Use the Beacons app to configure the power level for a proximity beacon, view the location beacon signal
range, and test your push notification campaigns to ensure that they are triggered at the appropriate locations.
Power levels can then be adjusted through the Beacons app or your Meridian editor account.
18. Aruba Beacons | Validated Reference Design Deploying and Configuring Beacons | 18
Chapter 4
Deploying and Configuring Beacons
Use the following procedures to download and install the Aruba Beacons application, add and configure a new
beacon, and place it on the location map.
You and your mobile device must be physically present in the location where you are deploying the beacon.
Install the Beacons App
To download, install, and log into the Beacons app:
1. Enable Bluetooth on your iOS mobile device.
2. From your iOS device, access the Apple App store and search for Aruba Beacons.
3. Download and launch the Beacons App
4. Log in to the app using your existing Meridian login credentials.
Figure 11 Install the Beacons App
Add a New Beacon
Use the following procedure to add a new location or proximity beacon to a location in your Meridian account.
1. Tap the accounts icon ( ) at the bottom of the screen to open the Accounts tab. The site locations from
your Meridian account appear in the tab.
2. Tap an organization to select the site for the new beacon.
3. Tap the maps icon ( ) to open the Maps tab.
4. Click the menu icon ( ) in the upper left corner of the screen, and select the floor on which the beacon is
located.
5. Bring the iOS mobile device close to the beacon and click the beacons ( ) icon to open the beacons list.
Data from nearby beacons are uploaded into the Beacons app. A green icon ( )next to a beacon indicates
19. 19 | Deploying and Configuring Beacons Aruba Beacons | Validated Reference Design
it is currently unplaced and available. A gray icon ( )indicates that the beacon is associated with a
different location in your Meridain account. A lock icon ( ) means the beacon is part of a different
account and you do not have access privileges to edit that beacon.
6. Tap the Unplaced button to view unconfigured beacons that are not yet placed on the map. You can
identify the beacon to be placed by its MAC address.
7. Tap and hold the beacon icon for the beacon you want to add, then drag the icon to the left side of the
screen. The floor map appears.
8. Drop the beacon icon on the appropriate place on the map.
9. The Beacon Type pop-up window prompts you to identify the beacon as a location beacon or a proximity
beacon. Tap Proximity or Location.
l If you select Location, the beacon is configured as a location beacon, and placed on the map. The
location beacon is represented by the blue location ( ) icon.
l If you select Proximity, you are prompted to select a power level for the beacon before the beacon is
placed on the map. Refer to the table below for details on proximity beacon power levels. The proximity
beacon is represented by the blue proximity ( ) icon.
10. Tap Save.
Figure 12 Add a New Beacon
The following table describes the power levels available for proximity beacons. By default, a proximity beacon
sends signals at a Level 14 signal strength (0 dBm). For more information on managing proximity beacon
power levels, see Beacon Power Levels.
Beacon Power Level TX power (dBm)
0 -29
1 -27
2 -25
Table 1: Proximity Beacon Power Levels
20. Beacon Power Level TX power (dBm)
3 -23
4 -21
5 -18
6 -16
7 -14
8 -12
9 -10
10 -8
11 -6
12 -4
13 -2
14 0
15 4
View Beacon Signal Strength and Density
The beacon signal strength seen by a mobile device is determined by a beacon's power setting and the location
where the beacon is installed. Follow the procedure below to view the signal strength of a location beacon, as
seen by an iBeacon-enabled client.
The signal strength display is not meant for precise fine-tuning of beacon placement or beacon signal strength
levels, but to give you a general idea of signal density and coverage areas.
1. Open the Aruba Beacons app.
2. From the Maps tab, click the filters icon ( ) icon
3. Tap Location
4. Tap Signal Strength to view the signal density for location beacons.
As shown in Figure 13 , the map displays the beacon signals detected by the mobile device. If the circle between
your device and the beacon is large, that indicates that the beacon is farther away from the mobile device and
has a weaker signal. If the circle between your device and the beacon is small, that beacon is closer and has a
stronger signal.
Note any areas on the map that are not covered by a beacon signal. If your deployed beacons do not fully
cover the desired area for your venue with location beacon signals, consider adding beacons, increasing the
signal strength or moving the beacon to a different location to avoid elements that may be blocking the
bluetooth signal. If the signal coverage density is very high, you may want to consider spacing the devices
further apart.
Aruba Beacons | Validated Reference Design Deploying and Configuring Beacons | 20
21. 21 | Deploying and Configuring Beacons Aruba Beacons | Validated Reference Design
Figure 13 Beacon Signal Strength
22. Aruba Beacons | Validated Reference Design Beacon Management | 22
Chapter 5
Beacon Management
Use an Aruba USB beacon installed into the USB port of an Aruba AP or the beacon built in to AP-320 series AP
to connect your battery-powered beacons to your Meridian account. Either of these types of beacons allow
you to remotely monitor and manage battery-powered beacons withing the range of a beacon in an Aruba AP.
Beacon Management Workflow
Battery-powered beacons advertise their configuration to the beacon in an AP, and check for available config
updates from a USB beacon every 500ms. The USB beacon uses information from battery powered beacons
to update the BLE table on the AP. The controller then periodically sends the AP BLE table to Meridian via a
secure (HTTPS) connection, and checks for config change requests from Meridian.
If any config changes are requested, the controller sends the config updates to the AP. The beacon in that AP
pushes out the config changes to the battery beacon as a response to a battery beacon advertisement, the
next time the battery beacon checks for an update. Messages passed between the USB beacon and the battery
beacon are small (<50 byte) packets that follow the BLE protocol.
Figure 14 Beacon Management Topology
The first time the controller is configured to contact Meridian, the controller contacts Meridian every ten
minutes. Once the controller sends an AP BLE table to Meridian, the controller sends updates more frequently;
every five minutes.
When a configuration change is requested through your Meridian account, the beacon in the AP pushes
updated config settings to the battery-powered beacons the next time the battery beacon checks for updates.
The controller sends status updates to Meridian once a minute until the requested changes are made and
confirmed on the network.
Beacon Management Considerations
Every ten minutes, a battery-powered beacon increases its transmission power level for five seconds, allowing it
to send status messages and receive configuration updates from a USB beacon that might otherwise be out of
range. Because there is a longer interval between HiPower beacon transmissions, battery-powered beacons
sending status messages at low power levels and high-power proximity beacons located very far away from the
AP may not be frequently heard by the USB beacons. This HiPower beacon interval, combined with the update
intervals between the controller and Meridian account, means it may take up to an hour for a low-power or
very distant proximity beacon to be recognized by Meridian.
If a USB beacon is installed in a ceiling-mounted AP, there may be some reduction in signal strength that
impacts how well it sees other beacons. To improve the range at which the USB beacon can detect other
23. 23 | Beacon Management Aruba Beacons | Validated Reference Design
beacons, consider using a USB extension cable to move the USB beacon into better location not impacted by
signal attenuation factors such as walls or wireless speakers.
Controllers running ArubaOS 6.4.3.3 or later can report to Meridian a maximum of 70 beacons per AP. This
maximum capacity will be enhanced in later versions of ArubaOS.
Managing Campaigns
Campaigns are the mechanism by which a push notification such as a customized message or link is sent to
mobile devices that are using a Meridian-powered app. When devices using the Meridian-powered app come
within range of a proximity beacon, the app triggers push notifications for the campaign asigned to the
proximity beacon. If your beacon deployment uses proximity beacons to trigger push notifications within your
Meridian-powered app, you must create and manage your campaigns using the Meridian Editor.
Notifications can be scheduled to trigger when a mobile device first comes within range of the proximity
beacon, or scheduled to coincide with a specific event or marketing campaign. For details on using the Meridian
Editor to define campaigns for deployed proximity beacons, see Configuring and Testing Campaigns.
Before you Begin
Before you can use a USB beacon in an Aruba AP or an AP-320 series access point to manage the battery-
powered beacons associated with your Meridian account, you must perform some additional network
configuration tasks to configure your network and Aruba controller to securely access your Meridian account in
the cloud.
Configure the Controller
The following procedures describe the steps to configure the controller with the required data for your beacon
deployment; the URL of the Meridian Editor (BLE URL) and the access token data from your Meridian account.
Using the WebUI
To configure the controller with the BLE URL and the authorization token for your Meridian account using the
controller WebUI:
1. Log in to your Meridian account with a Meridian username and password that grants you organization-level
privileges.
2. Click the Beacons link on the toolbar on the left side of the page.
3. Click the settings ( ) icon on the upper right corner of the page. The Beacons > Settings page opens.
4. In the Controller Configuration section, copy the BLE URL and Access Token strings into your clipboard
or a text file.
24. Figure 15 Controller Config Settings in the Meridian Editor
5. Next, log in to the Aruba controller managing your WLAN.
6. Navigate to Configuration > Advanced Services > All Profiles.
7. In the left window pane, Click AP to expand the AP menu.
8. Click AP system to expand the AP system menu.
9. Select the AP system profile for the access point that contains an Aruba beacon.
10. Click the Advanced tab.
11. Enter the BLE URL into the BLE Endpoint URL field.
12. Enter the access token into the BLE Auth Token field.
13. (Optional) If your network has APs that use a different AP system profile, repeat steps 9-12 to apply these
changes to the AP system profiles for any other AP with a USB or built-in beacon.
14. Click Apply.
15. Click Save Configuration.
Aruba Beacons | Validated Reference Design Beacon Management | 24
25. 25 | Beacon Management Aruba Beacons | Validated Reference Design
Figure 16 BLE Settings in the Controller AP System Profile
Using the CLI
To configure the controller with the Meridian Editor URL and Meridian authorization token using the controller
command-line interface, access the controller command-line interface in config mode, and issue the following
commands:
(host)(config)# ap-system profile <profile-name>
(host)(AP system profile <profile-name>)# ble-url <URL>
(host)(AP system profile <profile-name>)# ble-token <token>
For example:
(host)(config)# ap-system profile default
(host)(AP system profile "default")# ble-url https://edit.meridianapps.com/api/beacons/manage
(host)(AP system profile "default")# ble-token
NGE3MjUwZTUtYTkyMi00NmViLTg3MzEtN2NiODM4ZDQ4ZjkyOmU0ZGU3ZGE4LTExZmMtNDJjMS05OGY0LTkxZWFlMzdjMT
U5Qg==
Firewall Security
The controller contacts Meridian using HTTPS on port 443. Ensure that this port is open in your firewall, or the
communication between the controller and your Meridian account will be blocked.
Configure a DNS server
The controller must have access to a DNS server so it can resolve the Meridian URL and communicate with your
Meridian account in the cloud.
1. From the controller command-line interface, issue the command ip name-server <dns-server-ip> to add
a DNS server to your controller.
26. 2. If prompted, save your configuration settings and reboot the controller. The controller may not recognize
the DNS server until after it reboots.
Install the USB Beacon
AP-220 series, AP-210 series, and later model access points support USB-powered Aruba beacons. If you are using
the beacon in an AP-320 series AP to manage the battery-powered beacons in your deployment, you can skip this
task, and proceed to Verify the Controller Configuration.
To install the USB beacon , insert the beacon into an available USB port on a compatible AP that is powered on
and active on the network. Figure 17 shows the USB beacon being installed into the USB port on an AP-210
Series access point.
Figure 17 Inserting the Beacon into a USB port
Once the beacon is installed, access the controller and reboot the AP. The AP will not recognize an installed USB
beacon until it reboots.
To reboot the AP from the controller WebUI,
1. Navigate to Configuration > AP installation.
2. Click the checkbox by the AP you want to reboot then click Provision. The provisioning window opens.
3. Scroll down and click Apply and Reboot.
To reboot the AP from the controller command-line interface, access the command-line interface in config
mode and issue the command apboot ap-name <ap-name> to reboot the AP.
Verify the Controller Configuration
After the AP reboots, you must verify that the USB beacon is powered up and active on the AP. To do this,
access the controller command-line interface and issue the command show ap debug ble-table ap-name
<name> to display the beacons table. Check to see if the MAC address for the recently installed USB beacon
appears in the BLE table. If it appears in the table, that device powered up correctly. In this example, the entry
for the USB beacon highlighted in yellow shows that it is powered on, active on the network, and has an uptime
of five minutes and 40 seconds.
(host) # show ap debug ble-table ap-name AP1
BLE Device Table
Aruba Beacons | Validated Reference Design Beacon Management | 26
27. 27 | Beacon Management Aruba Beacons | Validated Reference Design
----------------
MAC HW_Type FW_Ver Flags Status Batt(%) RSSI Major# Minor#
UUID Tx_Power Last Update Uptime
--- ------- ------ ----- ------ ------- ---- ------ ------ ---
- -------- ----------- ------
7a:65:04:15:25:2e LS-BT1 OAD A 1.0-28 0x0011 IA 100 -87 4932 252
4453384E-F99B-4A3B-86D0-9470S8FJ33A78 14 8s 260d:3h:46m:0s
7a:a5:04:15:2f:59 LS-BT1 OAD B 1.0-35 0x0003 IAH 100 -92 1000 1017
237338E1-A8CD-4733-9D4E-E7SDD4B4A5DA 14 172s 80d:23h:50m:0s
6c:e9:ef:1e:3a:58 LS-BT1 OAD B 1.1-4 0x0003 IAH 100 -87 0 0
2352554E-F99B-4SCT-86D0-947070693A78 14 117s 17d:17h:16m:30s
b4:99:4c:5a:ba:23 LS-BT1USB OAD B 1.1-24 0x0083 LIA USB -- 16005 16766
23338DEA-1SCT-404B-874D-29AC20909D58 15 10s 0d:0h:05m:40s
Total beacons:3
Note: Battery level for LS-BT1USB devices is indicated as USB.
Note: Uptime is shown as Days hour:minute:second.
Note: Last Update is time in seconds since last heard update.
Status Flags:L:AP's local beacon; I:iBeacon; A: Aruba Beacon; H: Aruba HiPower Beacon
:U:Image Upgrade Pending
Monitoring and Managing Beacons with Meridian
To view and change settings for a beacon on your network:
1. Log in to your Meridian account.
2. Click the Beacons tab.
3. Click the Filters drop-down and to select the map and floor with the beacon you want to manage. The
beacons for that location appear in a table beside the location map.
Figure 18 Beacons at the Selected Location
4. Select any beacon in the table to view the following details for that device
l Device Name
l Type (proximity or location)
l Power (for proximity beacons only)
l MAC address
28. l Major/Minor values
5. To edit the device name, type, or (for proximity beacons only) the transmission power level, click Edit.
6. Make the required changes, then click Save to save your settings.
Requests for changes are sent to the controller the next time the controller contacts Meridian. Once the
controller verifies the configuration is updated on the battery beacon, the controller communicates this to
Meridian during the next update interval.
Troubleshooting
To verify that the AP and controller has received the configuration change request from Meridian, access the
controller's command-line interface and issue the command show ap debug ble-update-status ap-name
<ap-name>. The requested configuration change should appear in the Desired/Pending column. The
example below shows a requested power change for a beacon with the MAC address.
(host) # show ap debug ble-update-status ap-name AP1
BLE Device Table
----------------
BLE Device MAC Actual/Observed Desired/Pending
-------------- --------------- ---------------
5c:31:3e:fd:8e:4e 14 15
6c:ec:eb:1e:30:9d 14 14
6c:ec:eb:1e:30:9d 16005 16005
6c:ec:eb:1e:30:9d 16773 16773
5c:31:3e:fd:8e:4e 16005 16005
5c:31:3e:fd:8e:4e 16804 16804
Total beacons:6
Devices marked "Ineligible" are currently not capable of being upgraded.
Run the command again after some time to see if the change has taken effect.
(host) # show ap debug ble-update-status ap-name AP1
BLE Device Table
----------------
BLE Device MAC Actual/Observed Desired/Pending
-------------- --------------- ---------------
5c:31:3e:fd:8e:4e 15 15
6c:ec:eb:1e:30:9d 14 14
6c:ec:eb:1e:30:9d 16005 16005
6c:ec:eb:1e:30:9d 16773 16773
5c:31:3e:fd:8e:4e 16005 16005
5c:31:3e:fd:8e:4e 16804 16804
Total beacons:6
Devices marked "Ineligible" are currently not capable of being upgraded.
Ineligible Devices
The output of the show ap debug ble-update-status command may include a note about ineligible devices.
The ineligible flag was applied to some very early versions of Aruba beacon which were not capable of
configuration upgrades. This issue was resolved in subsequent releases, and now all Aruba beacons currently
being sold support configuration upgrades.
Hi-Power Beacons
For distant or lower-power beacons that the USB beacon cannot hear very well, use the show ap debug ble-
counters ap-name <name> command to check when a battery beacon goes to HiPower mode. The HiPwr
column of the BLE device table shows the number of times the AP detected the beacon transmitting in Hi
Power mode.
Aruba Beacons | Validated Reference Design Beacon Management | 28
30. Aruba Beacons | Validated Reference Design Configuring and Testing Campaigns | 30
Chapter 6
Configuring and Testing Campaigns
A campaign is the mechanism by which location and time-based push notifications are sent to visitors using a
Meridian-powered app. Campaigns designed to push location-based notifications send a customized message
or link to a mobile device running a Meridian-powered app when that device first comes within signal range of a
proximity beacon associated with that campaign. Campaigns can also send time-based push notifications to
mobile devices according to a defined schedule. Time-based campaigns can send a message or link to a device
running a Meridian-powered app if that device comes in range of a proximity beacon during a selected time
range, or send messages to users in signal range of a proximity beacon on a regular, reoccurring schedule, such
as every Wednesday, or the first Saturday of every month.
Meridian campaigns can also notify your own custom endpoint when a device with a Meridian-powered app
comes within range of a proximity beacon associated with that campaign, passing along login information for
that user, as well as information about the venue location and campaign that was triggered.
Meridian campaigns automatically throttle the rate of notifications sent to a single user by observing a
cooldown period between broadcasts, ensuring that no single user is subjected to excessive campaign
notifications while they remain in your venue. Even if you have multiple campaigns defined within one area of
your venue, Meridian will only send a notification to the same device once every 5 minutes, and a campaign can
only be triggered by the same device once every 12 hours.
This chapter describes the basic steps to configure and test a push notification campaign. For complete
information on creating a campaign using the Meridian Editor, refer to the Meridian online help at
http://docs.meridianapps.com/help/beacons_app_deploy.
Creating a Campaign
Use the following procedure to configure a campaign with the Meridian Editor that triggers an action on an
iBeacon-compatible, Bluetooth-enabled device when that device comes in signal range of an Aruba proximity
beacon.
When configuring and associating campaigns with proximity beacons, keep in mind that iOS devices can not process
more than twenty push notifications, regardless of the number of proximity beacons around the device.
1. Log into your Meridian Editor account at https://edit.meridianapps.com, and select the venue location
where you want customers to receive push notifications. Note that there is approximately a ten minute
delay between the time a proximity beacon is first deployed and the time that beacon appears in the
Meridian editor.
2. Select Campaigns.
3. Click the floor drop-down list at the top of the map, and select a floor.
4. Click the add (+) icon in the upper right corner of the window to associate a new campaign to a beacon on
the selected floor.
5. Enter a title for the new campaign, then click OK.
6. Click on any beacon on the floor map to associate that beacon to the campaign. The Editor displays a
popup window in which you can define the campaign settings.
7. Click the Action drop-down list and select one of the following options:
l Send device a message: Send a message to the iBeacons-enabled device.
l Notify a custom end-point: Send a query to a specified URL.
31. 31 | Configuring and Testing Campaigns Aruba Beacons | Validated Reference Design
8. Configure the message text or endpoint URL.
9. Select one of the following broadcast types:
l Always: Perform the specified action every time the action is triggered
l Scheduled: Perform the specified action during the specified time frame. You can also define a
repeating schedule, for actions that should repeat on a weekly or monthly schedule.
10. Click Activate Campaign.
11. Click Save to save your settings. Once the campaign is associated to a beacon, the campaign name will be
highlighted in the Meridian Editor when you hover your mouse over that beacon.
Figure 19 Creating a Campaign using the Meridian Editor
Testing a Campaign
Once you have defined a campaign, you can use the Beacons app to test a campaign associated with your
Meridian account. Note that the Beacons app is only used to test existing campaigns; new campaigns must be
configured using the Meridian Editor.
You and your mobile device must be physically present in the location where you are testing the campaign.
Use the following procedure to test an active campaign using the Beacons app.
1. To simplify the testing procedure, reduce the range of the proximity beacon by lowering its transmit power
level. Start the test by standing farther away from the beacon (outside its range).
2. Tap the campaigns icon ( )to display the Campaigns tab, then tap and select an active campaign. Once
you have selected a campaign, the Beacons app displays information about the selected campaign,
including the action type, message or query URL, and broadcast schedule.
3. Tap the maps icon ( ) at the bottom of the screen to begin the test.
32. The mobile device running the Beacons app appears on the map as a small blue dot if beacons are
deployed in the area. The beacon(s) associated with the campaign appear on the map as a blue or green
pointer icon.
l Blue pointer icon ( ): The mobile device is outside the range of the proximity beacon.
l Green pointer icon with a signal meter ( ): The device has come within range of the beacon, and
the push notification is triggered.
l Green pointer icon with exclamation point ( ): The device moved outside the range of the
proximity beacon after the notification was triggered.
l Green pointer icon with exclamation point and timer ( ): The device moved outside of the
range of the proximity beacon after the notification was triggered, and the campaign cooldown period
has begun.
4. Move the mobile device closer to the proximity beacon, until the beacon appears as a green pointer icon
with a signal meter, and the push notification is triggered on that device.
5. Move the mobile device further away from the beacon, until the device is outside the beacon's range. This is
when the 30 second cool-down period starts, as indicated by the green beacon icon with the timer.
Once your mobile device is out of range of the beacon, that device will not receive a duplicate notification from
that beacon until the campaign is reset. If you are outside the range of the beacon for the entire 30-second
cooldown period, the beacon icon will appear as a blue pointer again, meaning you can manually reset the
campaign associated with the beacon and run the test again.
Campaigns are automatically reset 12 hours after the device moves and remains out of range of the beacon.
To manually reset all campaigns for your device:
1. Tap the campaigns icon ( ) to display the Campaigns tab.
2. Click Reset. A popup window appears, indicating that "Campaign cooldowns have been reset."
Aruba Beacons | Validated Reference Design Configuring and Testing Campaigns | 32
33. Aruba Beacons | Validated Reference Design Transmission Power Levels | 33
Appendix A
Transmission Power Levels
The beacon Received Signal Strength Indicator (RSSI) seen by a iBeacon-enabled client depends upon the
beacon's power level, orientation, and the distance from the client. The signal strength is greatest for clients
directly in front in the beacon. A client located to the side of the beacon or behind the beacon may detect a
slightly lower signal strength than a client directly in front of the beacon, even if those clients are the same
physical distance from the beacon.
Table 2 shows the results of informal RSSI testing for a sample beacon at the default power level 14, measured
at varying distances from the beacon, and either directly in front of the beacon (0 degrees), behind the beacon
(180 degrees), to the left side of the beacon (-90 degrees), and the right side of the beacon (90 degrees).
Measurements were taken by the Texas Instruments Bluetooth low energy Multitool app on an iPhone 5C.
Table 2: RSSI Testing at Power Level 14
Distance (m) RSSI, in -dBm
0 degrees 180 degrees -90 degrees 90 degrees
1 68 70 -75 67
2 72 71 80 72
3 78 76 79 76
4 80 81 83 82
5 81 83 84 83
7 84 84 86 84
9 86 87 90 88
11 92 83 89 89
14 95 88 86 92
17 94 86 91 94
20 94 90 94 98
25 94 94 93 99
Table 3 below shows the results of informal RSSI testing for a beacon at power level 11.
34. 34 | Transmission Power Levels Aruba Beacons | Validated Reference Design
Table 3: RSSI Testing at Power Level 11
Distance (m) RSSI, in -dBm
0 degrees 180 degrees -90 degrees 90 degrees
1 75 75 82 72
2 76 76 85 78
3 85 81 88 82
4 83 84 90 86
5 92 89 91 88
7 86 92 93 92
9 91 93 95 94
11 95 94 96 96
14 92 95 97 95
17 98 94 100 100
20 100 97 99 102
25 102 98 102 *
* RSSI value could not be measured.
Table 4 below shows the results of informal RSSI testing for a beacon at power level 3.
Table 4: RSSI Testing at Power Level 3
Distance (m) RSSI, in -dBm
0 degrees 180 degrees -90 degrees 90 degrees
1 91 93 101 90
2 97 91 100 95
3 98 95 * 97
4 100 99 * 102
35. Distance (m) RSSI, in -dBm
5 101 101 103 *
7 103 * * *
9 (and greater) * * * *
* RSSI value could not be measured.
Aruba Beacons version 1.0.8 and later versions of the Beacon app provide more granular transmission power
settings for proximity beacons than earlier versions. The following table shows the correlation between the old
transmission power settings in the earlier version of the app, and the power settings available in the current
versions.
Table 5: Transmission Power Settings
Aruba Beacons | Validated Reference Design Transmission Power Levels | 35