Juniper JN0-253 Mist AI - Associate (JNCIA-MistAI) Exam Practice Test

InJuniper Mist’s Location-Based Services, theAsset Visibilityservice utilizes the built-inBluetooth Low Energy (BLE)antenna array within Mist Access Points to track BLE tags and devices inlisten-only mode. This allows the APs to receive BLE signals emitted by assets and compute their real-time location usingangle-of-arrival (AoA)andRSSI-based triangulation.

According to theJuniper Mist Asset Visibility and Location Services Guide:

“When operating in Asset Visibility mode, the vBLE antenna array in Mist Access Points functions in listen-only mode, collecting BLE chirps from asset tags and relaying this data to the Mist Cloud for location determination.”

This configuration differs fromvBLE Engagement, where APs transmit BLE beacons to interact with mobile apps. InAsset Visibility, the BLE array passively listens to track tagged assets (e.g., equipment, IoT devices) across a defined floor map.

Therefore, the correct answer isD. Asset Visibility.

Juniper Mist Wired Assurance delivers robust automation for campus and remote switches by supporting both template-based configuration for switches and port profiles as core features. According to the official Juniper Mist documentation, "Wired Assurance provides cloud-managed switch configuration through scalable templates. These templates are set at the organization or site level, standardizing VLANs, port settings, security options, and other operational parameters for all managed EX and QFX series switches." Furthermore, port profiles allow administrators to automate port assignment and behavior based on dynamic criteria such as LLDP information or MAC addresses: "Dynamic port profiles are applied automatically when specific criteria are detected, simplifying operational workflows and reducing manual errors."

Features like "template-based configuration for routers" and "WxLAN policies" are not part of Mist Wired Assurance. Router configuration is enabled in Routing Assurance, and WxLAN is a Juniper-specific campus automation solution, not directly related to switch management.

Verification:

This aligns with the selections marked in your image ("template-based configuration for switches" and "port profiles"). It is fully verified by Juniper's official guides for Mist Wired Assurance.

To use Marvis Minis, both theWiFi Management and AssuranceandMarvis for Wirelesssubscriptions are required. According to the official Juniper documentation, Marvis Minis "does not require a separate subscription. Any organization with an active Marvis for Wireless subscription is automatically entitled for Marvis Minis support." However, the Marvis for Wireless subscription operates on top of the foundational WiFi Management and Assurance subscription, which is necessary to operate APs and the wireless network within the Mist Cloud. As stated: "In addition to your base Assurance subscriptions (Wireless Assurance, WAN Assurance, or Wired Assurance), you also need Marvis subscriptions for each device..." Therefore, both are prerequisites for using Marvis Minis, ensuring full wireless management with AI-powered digital twin validation.

In theJuniper Mist Cloud, theSubscriptionspage provides administrators with detailed information about the status of service licenses and subscriptions associated with devices, sites, and organizations. This includes visibility into the number of active devices, sites, and anyunused subscriptionsacross the organization.

According to theJuniper Mist Cloud Licensing and Subscription Management Guide, the “Sites” section under Subscriptions Summary shows:

“The total number of configured sites within the organization and the number of sites that currently do not have assigned subscriptions.”

In the exhibit, the summary shows:

82 Sitestotal

15 Unusedsites

This indicates that15 sites currently have no active or assigned Marvis for Wireless subscriptions. The “Unused” label under Sites refers specifically to the count of sites not yet utilizing their allocated subscription entitlements.

Therefore, the correct answer isB. 15.

InJuniper Mist AI, variousmachine learning (ML)techniques are applied across the platform to analyze network telemetry and improve performance insights. Among these,unsupervised learningplays a critical role in identifying patterns, trends, and anomalies in unlabeled datasets—data that has not been pre-classified or annotated.

According to theJuniper Mist AI and Machine Learning Overview:

“Unsupervised learning enables Mist AI to automatically detect abnormal patterns or clusters in large volumes of unlabeled network data, allowing the system to identify anomalies and optimize network behavior without human labeling.”

This method allows Mist AI to autonomously recognize deviations in user experience, traffic behavior, or radio performance without prior definitions, helping to enhance predictive analytics and anomaly detection.

By contrast:

Supervised learningrequires labeled training data.

Reinforcement learninglearns through trial-and-error feedback loops.

Cognitive learningis not a formal ML category—it refers to human-inspired reasoning.

Therefore, the correct answer isD. Unsupervised learning.

In theJuniper Mist Cloud architecture, configuration hierarchy and inheritance are key design principles for managingEX SeriesandQFX Seriesswitches underWired Assurance. Configuration settings can be applied at both theorganization leveland thesite level, with clearly defined precedence rules.

According to theJuniper Mist Wired Assurance Configuration Guide, theorganization leveldefines global configuration templates that apply across multiple sites, while thesite levelprovides customization options specific to a particular location or environment.

The documentation states:

“Site-level configuration overrides any global or organizational template configurations for switches within that site.”

and further clarifies:

“Administrators can create or modify switch templates at the site level to apply custom settings to specific deployments without affecting other sites under the same organization.”

Thus:

Statement Cis correct — site-level configurations are an additional method to apply templates for a specific site.

Statement Dis correct — site-level configurationstake precedenceover org-level templates.

Statement Ais incorrect because org-level templates donotoverride site-level configurations; the reverse is true.

Statement Bis incorrect because site-level configuration isnot requiredfor manual switch setup—it is an optional, more efficient method of template application.

TheJuniper Mist Wired Assuranceplatform uses ahierarchical configuration modelto manage switch settings efficiently across organizations and sites. This hierarchy provides flexibility by allowing administrators to applyglobal configurationsthrough templates at theorganization level, while also permitting site-specific customizations.

According to theJuniper Mist Wired Assurance Configuration and Template Management Guide, the configuration hierarchy functions as follows:

“Switch templates can be created at both the organization and site levels. Organization-level templates define global configurations, while site-level templates provide location-specific customization that overrides the organization-level settings where applicable.”

This structure enables consistent policy deployment while preserving site autonomy for unique configurations. For example, global VLAN or QoS configurations can be managed at the organization level, and local templates can adjust settings for switch ports or device groups at specific sites.

Switch-specific overrides are allowed within the hierarchy, ensuring flexibility in cases where unique port or feature configurations are required.

Therefore:

Bis correct because switch templates exist at theorganization levelfor global use.

Cis correct because switch templates also exist at thesite levelfor localized adjustments.

In theJuniper Mist Cloud, aWLAN templateis used to standardize and simplify the configuration of wireless networks across multiple sites. Templates define common wireless parameters, ensuring consistent deployment and easier scalability while reducing configuration errors.

According to theJuniper Mist Wireless Assurance Configuration Guide, WLAN templates contain several configurable elements that define how the wireless network operates, including:

Radio Management (A)This element controlsRF parameterssuch as transmit power, channel width, and radio band assignments (2.4 GHz / 5 GHz / 6 GHz). It leverages Mist’sAI-driven Radio Resource Management (RRM)to optimize RF performance across APs dynamically.

WLANs (D)The template includesWLAN definitions(SSIDs) with associated settings such as authentication type, VLAN assignment, access control policies, and bandwidth limitations. WLANs can be linked to specific sites through these templates for unified management.

The other options are incorrect:

Template Policies (B)are not a defined component within WLAN templates—they refer to higher-level configuration management.

Organizations (C)exist at the top hierarchy level in Mist Cloud (above sites and templates) and are not configured within a WLAN template.

Therefore, the two correct configuration elements available in a WLAN template are:

A. Radio management

D. WLANs

TheInstallerrole in theJuniper Mist Cloudis atemporary, limited-access account typeused for onboarding network devices—typicallyAccess Points (APs)—during initial deployment. It provides restricted visibility and configuration rights necessary for installation tasks but expires automatically after a definedgrace periodto maintain network security and access control.

According to theJuniper Mist Cloud Administration and User Management Guide:

“The Installer role provides temporary access to add, claim, and verify devices at a site. This access expires automatically after the predefined installation grace period.”

This role is ideal for field engineers or contractors performing device installations without granting them long-term administrative privileges. The grace period is typicallyseven days, after which the Installer account loses access to the organization automatically.

Other roles differ as follows:

Super Observer:Read-only access across the entire organization.

Observer:Read-only access limited to assigned sites.

Helpdesk:Focused on monitoring and basic troubleshooting tasks, not installation.

Therefore, the correct answer isB. Installer.

Dynamic Packet Capture and Radio Resource Management (RRM) are two key components of WiFi Management and Assurance in Juniper Mist. According to official documentation: "Dynamic packet capture allows capturing wireless packets between clients and an access point to diagnose root-cause wireless issues. For example, when a major issue is detected, such as an authorization failure, packet captures facilitate quick troubleshooting and root-cause analysis." RRM, driven by Mist’s AI, proactively analyzes network conditions and client experiences to automatically adjust channel and power settings for optimal performance: "AI-driven RRM uses data science and cumulative SLE performance to learn and optimize radio settings, helping RF planning to continue to improve and adapt in the changing environments..."

Marvis Actions is an AI-powered troubleshooting feature, but it is a separate component enabled by the Marvis subscription, not by base WiFi Management and Assurance. Wayfinding is part of the vBLE Engagement or location services.

Juniper Mist Location Services provide asset location and wayfinding. According to official Juniper documentation: "Juniper Mist provides location accuracy for wayfinding, asset visibility, and user engagement," leveraging cloud-native vBLE and Wi-Fi technologies.

Asset location enables organizations to locate high-value resources, personnel, or IoT devices in real time with rich analytics, making it easy to find assets and people using the Mist dashboard and APIs.

Wayfinding gives users turn-by-turn indoor navigation and mapping via mobile SDKs and the Mist cloud.While geofencing can be achieved as part of location-based engagement features, it is not listed as a primary Mist Location Service solution. GPS location is not directly supported; Mist Location Services operate indoors using Wi-Fi and BLE signals, not satellite GPS.

In theJuniper Mist Marvis Actions dashboard, issues and recommendations are displayed with status labels indicating their progress and resolution method. One of these statuses isAI VALIDATED, which signifies that the issue was automatically detected, diagnosed, and resolved byMarvis AIwithout requiring manual intervention.

According to theJuniper Mist Marvis Virtual Network Assistant Operations Guide:

“AI VALIDATED indicates that Marvis has confirmed and resolved a network issue autonomously using AI-driven automation and telemetry correlation.”

This means Marvis performed the full troubleshooting cycle—identifying the anomaly, validating its cause, and confirming resolution—based on continuous monitoring and real-time network analytics.

Other statuses include:

UNRESOLVED:Issue is ongoing and needs attention.

RESOLVED:Marked manually by an administrator after resolution.

AI VALIDATED:Confirmed and closed automatically by Marvis AI.

Therefore, the correct answer isA. The issue was identified and resolved entirely by Marvis.

Thesession policy settingsin theJuniper Mist Clouddefine how long a user session remains active and how the system manages session expirations due to inactivity. These configurations help ensure bothsecurityandefficient resource managementacross the Mist Cloud portal and API sessions.

According to theJuniper Mist Cloud Administration and Security Configuration Guide:

“Session policy defines session timeout and inactivity timeout parameters, controlling how long users can remain logged into the Mist Cloud portal or API before re-authentication is required.”

Session Timeout:Specifies the maximum duration a session can remain active, regardless of activity.

Inactivity Timeout:Defines how long a session can remain idle before automatic logout.

These policies help maintain strong access security by reducing the risk of unauthorized access through stale sessions.

Other options such as password complexity (A, C) and two-factor authentication (D) are configured underauthentication and access policies, not session policies.

Therefore, the correct answer isB. The duration for session timeout and inactivity timeout.

ThePredictive Analytics and Correlation Engine (PACE)is the core AI engine that powers theJuniper Mist Cloud. It is designed to continuously learn from real-time telemetry and user interactions across wireless, wired, and WAN networks to proactively identify anomalies and predict performance issues.

According to theJuniper Mist AI Cloud and PACE Architecture Documentation, PACE:

“Leverages machine learning and advanced analytics to correlate data across millions of network sessions, automatically identifying patterns that affect user experience.”

The engine continuously evaluates key Service Level Expectations (SLEs), such asTime to Connect,Throughput, andRoaming, to establish performance baselines and detect deviations before users notice them.

PACE doesnot rely on manual analysisoruser feedback, and it integrates telemetry rather than external monitoring tools to maintain a closed-loop feedback system for self-correction and optimization.

Therefore, PACE usesmachine learning (A)to understand, predict, and improve end-user experience across Juniper Mist-managed networks.

The WAN Edge Health SLE in Juniper Mist monitors critical operational metrics for WAN edge devices. According to Juniper’s documentation: “Juniper Mist analyzes various factors that affect WAN edge health and assigns a score… Classifiers include Memory—triggered when WAN edge memory utilization is above 80 percent and CPU—triggered when control or data plane CPU utilization is above 90 percent.” These components directly impact the device’s ability to process traffic. Monitoring these parameters enables rapid detection of system resource constraints, which are essential for ensuring optimal WAN performance. While ISP reachability is a separate SLE (usually part of WAN Link SLEs), application response times are tracked in Application SLEs.

In theJuniper Mist Cloud architecture, bothwebhooksandAPIsare key interfaces for automation, integration, and data exchange with third-party systems. While they both facilitate communication between Mist and external applications, they operate inopposite directionsand serve distinct purposes.

According to theJuniper Mist API and Webhook Developer Guide:

Webhooksarepush-based notificationsinitiated by the Juniper Mist Cloud. When specific events occur (such as device disconnection, client onboarding, or alert generation), Mist sends structured JSON payloads to a preconfigured external URL endpoint.

APIs(Application Programming Interfaces) arepull-based querieswhere an external client polls the Mist Cloud to retrieve or update data (e.g., inventory, configuration, or metrics).

Additionally, the Mist Cloud enforcesrate limitson API calls to ensure platform stability and fair usage:

“API rate limits are applied on a per-organization basis to prevent excessive polling and to maintain consistent performance.”

In contrast, webhooks do not have a strict hourly quota because they are event-triggered rather than continuous requests.

Therefore:

Ais correct — Webhooks push, APIs pull.

Bis correct — There is an hourly API rate limit per organization.

OptionsCandDare incorrect because webhooks are event-based (not rate-limited hourly) and do not configure Mist objects directly—they only send notifications.

Two wired elements configured using an organization-level template in Juniper Mist are VLAN and DNS settings. Organization-level templates are designed to standardize and propagate common settings across all switches within an organization. As per official guides: "These templates can include VLANs and well-known services such as DNS (Domain Name System) that can be used across all devices within a site." VLAN and DNS settings are defined once at the organization (or switch group) template and automatically inherited by all devices, ensuring consistency. Host name and role are set at an individual switch level, not globally via templates.

Marvis Minisis a component of theMarvis Virtual Network Assistant (VNA)within theJuniper Mist AI ecosystem. It is designed to proactively ensure optimal network performance and user experience by runningsynthetic network testsusing Mist-managed access points.

According to theJuniper Mist Marvis Minis Technical Overview, this feature allows APs to act asvirtual clientsthat automatically simulate user connection flows, including authentication, DHCP, DNS, and application reachability. These tests validate that thenetwork configuration and servicesare functioning as expected, even before real users experience issues.

The documentation states:

“Marvis Minis operates in conjunction with Mist AI to continuously validate network configurations and optimize user experience by identifying potential problems proactively.”

“Using Mist APs, Marvis Minis performs synthetic transactions to verify the performance of wireless, wired, and WAN segments without requiring external devices.”

Hence,Marvis Minis is not a support team (A),not a design AI model (B), andMarvis Actions (C)is a different feature for identifying and resolving live issues. The accurate description is thatMarvis Minis collaborates with Mist AI to validate configurations and optimize user experiences.

Audit Logs in Juniper Mist are used to view a complete record of logins. The documentation states: "On the Audit Logs page, you can see who logged in to the Juniper Mist portal, when they logged in, and what they did." Audit Logs also record configuration and administrative actions by users on all sites within the organization, enabling administrators to track activity for compliance, troubleshooting, and security. This comprehensive record assists with accountability and change tracking, but they do not manage subscriptions, organization setup, or error logs for all devices. Filtering options allow for activity analysis over selectable time periods, by users, and by site to provide detailed insights into administrative behavior and user access history.​

Juniper Mist WAN Assuranceis a cloud-based service that extends Mist AI capabilities to the WAN edge, providing visibility, automation, and AI-driven analytics for WAN devices. It focuses on ensuringend-to-end service assurancefor users and applications across distributed networks.

According to theJuniper Mist WAN Assurance and SD-WAN Deployment Guide, the supported devices include:

“Juniper SRX Series Firewalls and Session Smart Routers (SSR) are integrated with Mist WAN Assurance for telemetry collection, service-level monitoring, and AI-driven troubleshooting.”

SRX Series Firewalls (A):Provide secure WAN connectivity and send real-time telemetry (including throughput, latency, and packet loss metrics) to Mist Cloud.

Session Smart Routers (C):Power the AI-driven SD-WAN solution with application-aware routing and session intelligence, fully integrated into Mist Cloud for advanced visibility and analytics.

EXandQFXswitches are used withWired Assurance, not WAN Assurance.

Therefore, the correct answers areA. SRX Series FirewallsandC. Session Smart Routers.

When developing areal-time visualization dashboardthat displays client locations on a map, Juniper Mist offers specific APIs and data streaming methods to support dynamic updates.

According to the Juniper Mist Developer Documentation, theWebSocketinterface enables continuous,real-time streaming of client location and telemetry datadirectly from the Mist Cloud. This mechanism is ideal for live dashboards, as it eliminates the need for repeated REST API polling. WebSocket connections provide instant updates whenever a device moves, connects, or disconnects, ensuring the displayed map remains accurate in real time.

TheLive Viewfeature complements this functionality within the Mist Cloud and third-party integrations. It allows administrators and developers toview live location movements of Wi-Fi clients, BLE beacons, and IoT deviceswithin a site’s floor plan. It uses telemetry directly from access points, offering second-by-second updates.

In contrast,RESTful APIsandWebhooksare designed for event-based automation and configuration management rather than live visualization. REST APIs are best for historical or static data retrieval, while Webhooks are used for triggering external actions based on events.

Therefore, the correct functions for real-time map visualization are:

WebSocket (C)— for continuous live data streaming

Live View (D)— for direct map-based visualization of client activity

In theJuniper Mist WAN AssuranceandSD-WANframework,Forwarding Insightsis the feature responsible for providingapplication forwarding path visibility. It delivers detailed analytics on how application traffic is being routed across the WAN, enabling network administrators to understand and optimize application performance across multiple WAN links or paths.

According to theJuniper Mist WAN Assurance and Insights Documentation,Forwarding Insights:

“Provides visibility into the application forwarding path by showing which WAN link or tunnel is used for a specific flow, including health metrics such as latency, loss, and jitter.”

It integrates withMarvisand theAI-driven WAN Assurance engineto automatically correlate user experience with network transport behavior. Administrators can use Forwarding Insights to:

Identify whichpath (primary, secondary, or backup)an application flow takes.

Viewreal-time performance metricssuch as round-trip delay and packet loss per path.

Understandwhy path selection decisions were made, based on policy or link health.

Other options are incorrect:

A. Router Insightsfocuses on routing and device-level performance, not per-application path details.

B. WAN Edge Insightsprovides device health and site connectivity data, not application-level forwarding analytics.

D. Platform Insightscovers cloud infrastructure performance, not WAN traffic analysis.

Thus, the correct answer isC. Forwarding Insights.

In the Juniper Mist Cloud Portal, theSubscriptionspage provides a summary of all service entitlements associated with an organization, including the number of licensespurchasedandonboardedfor each Mist Cloud service.

According to the official Juniper Mist Cloud Administration Guide, this section displays key fields such asService Name,Purchased,Onboarded,Start Date, andEnd Date. ThePurchasedcolumn indicates the total number of subscriptions bought, while theOnboardedcolumn represents how many of those have been actively assigned and deployed within the organization’s network.

In the exhibit, the entry forMarvis for Wirelessshows103 purchasedand82 onboarded, meaning that while 103 licenses were obtained, only 82 have been claimed and are in use within the system.

Therefore, the correct number ofonboarded Marvis for Wireless subscriptionsis82.

You must configure the site within your organization—this is the correct process according to Juniper Mist’s official configuration guides. When setting up a deployment, first an organization is created in the Mist cloud. Within this organization, sites are added for each physical location. The Mist documentation says: "You can create Sites in the Juniper Mist portal from the Organization > Site Configuration menu. Add or update sites as needed." The configuration requires the site name, country, and location to be set at the site level—not the organization level. Claiming APs via QR codes and organization definition are separate steps in device onboarding and initial setup.

Within theJuniper Mist Wireless Assurance dashboard, theCapacity SLE (Service Level Expectation)provides visibility into how well the network can handle concurrent users and traffic loads. It identifies the contributing factors, orclassifiers, responsible for degraded capacity performance such asWi-Fi interference, network issues, Ethernet problems, or authorization delays.

According to theJuniper Mist AI Operations and SLE Analytics Guide, the platform:

“Uses classifiers to break down SLE metrics and identify which network factors most heavily contribute to sub-threshold performance.”

In the exhibit, theWi-Fi interferenceclassifier has the longest bar reaching the full17%, clearly showing it as the largest contributor to capacity degradation. Wi-Fi interference occurs when multiple APs or nearby wireless networks overlap on the same channel, resulting in increased contention, collisions, and reduced airtime availability — all of which impact overall capacity.

Therefore, the correct answer isD. Wi-Fi Interference.

TheROAMINGOF elementis part of theMarvis Query Language (MQL), which is the structured query syntax used byMarvis, Juniper’sVirtual Network Assistant (VNA).

According to theJuniper Mist Marvis and MQL Technical Reference, Marvis Query Language provides advanced data query and automation capabilities that go beyond the conversational interface. It allows administrators to directly extract analytical insights, run network diagnostics, and perform queries related touser experience metricsandService Level Expectations (SLEs).

The documentation specifies:

“MQL is the analytical engine of Marvis that uses elements such as ROAMINGOF, CONNECTIVITYOF, and PERFORMANCEOF to query Mist data and retrieve SLE metrics, performance trends, and device events.”

TheROAMINGOFelement specifically relates to theWireless Roaming SLEcategory, enabling Marvis to evaluate client roaming performance across access points, identify failed transitions, and correlate signal quality or capacity-related issues.

While theConversational Assistant (A)uses natural language queries, it translates them internally intoMQLcommands.Marvis Minis (C)runs synthetic tests, andWireless SLE (D)displays performance metrics but does not directly use MQL syntax elements.

Thus, the correct answer isB. Marvis Query Language.

The feature that provides deep visibility into BGP operations for MX Series routers is Routing Assurance. According to official Juniper documentation: "Juniper Mist Routing Assurance provides insights about... routing, including routing events, routing protocol states, peer status analysis, routes, and more" for supported routers such as Juniper MX and ACX series. Routing Assurance extends Mist AI observability and analytics into the routing fabric, offering real-time visibility and telemetry for BGP peering session health, routing tables, events, path changes, and other core routing metrics. This empowers network operators with actionable insights and root cause analysis capabilities to maintain optimal WAN and core routing performance from the Mist cloud. Wired Assurance focuses on switch and port health and is not designed for routing protocol visibility.

The Juniper Mist REST API primarily provides functions for Juniper Mist configuration and historic statistics monitoring. According to the Juniper Mist documentation and API reference, the REST API allows users to automate configuration changes and retrieve historical data for analysis and reporting. Specifically, “configuration” functions include creating, updating, and deleting sites, devices, SSIDs, VLANs, templates, and user roles through API calls. “Historic statistics monitoring” refers to the API’s capability to pull time-series analytics on network and device performance, enabling users to query device usage, client events, SLE metrics, and application data over customizable timeframes.

Real-time statistics and event-driven monitoring are typically accessed via Mist’s WebSocket API, not the REST API. The REST API focuses on configuration management and historical data extraction for audit and trend analysis, supporting full automation and integration with third-party tools.

Verification:

These answers match the selections marked in your image ("Juniper Mist configuration" and "historic statistics monitoring") and are verified per Juniper’s API documentation and feature matrix.

InJuniper Mist AI, the concept of aBad User Minute (BUM)is a core metric used withinService Level Expectations (SLEs)and theAI-driven analytics engineto quantify negative user experience.

According to theJuniper Mist AI Operations and SLE Analytics Guide, a “bad user minute” is defined as:

“A normalized measure that represents one minute of degraded user experience for one user.”

Mist AI calculates this by multiplying the number of affected users by the number of minutes they experience poor performance. This allows administrators to understand the impact of network issues not just in duration, but in terms of total user experience degradation.

For example, if ten users experience poor connectivity for one minute, the system records10 bad user minutes. This normalization helps Juniper Mistprioritize incidents based on impact, rather than duration alone, allowing administrators to focus on issues that affect the greatest number of users.

Therefore:

Bis correct — it’s a way to normalize a user’s negative experience.

Dis correct — it’s calculated asnumber of affected users × number of minutes affected.

In theJuniper Mist Cloud architecture, aWLAN templateis used to define wireless network parameters, including SSIDs, authentication methods, and access control settings. These templates allow administrators to apply consistent Wi-Fi configurations across multiple access points and sites.

According to theJuniper Mist Wireless Assurance Configuration Guide, the WLAN template:

“Defines the configuration for SSIDs, including security mode (WPA2, WPA3, 802.1X), authentication servers, VLAN assignment, and user access policies.”

To configureWPA3/Enterprise (802.1X)security for employee SSIDs, administrators must create or edit a WLAN template and selectWPA3-Enterpriseas the security type. The template can then be associated with all sites in the organization, ensuring uniform deployment.

Other template types serve different purposes:

Switch template:Used for wired configuration and port profiles.

WAN Edge template:Used for SD-WAN and WAN Assurance configurations.

RF template:Used to manage radio parameters such as channel, power, and band.

Therefore, the correct answer isC. WLAN template.