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A network engineer is configuring QoS on a Cisco Catalyst 9300 switch to prioritize voice traffic. The switch has multiple access ports connected to IP phones and PCs. The engineer applies a policy-map that matches DSCP EF and sets the CoS to 5. However, after testing, the voice packets are not being marked correctly. What is the most likely cause?
2An enterprise is deploying a new VoIP system and wants to ensure voice traffic receives priority over data traffic on a WAN link. The engineer configures a class-map to match RTP traffic using the 'match protocol rtp' command. However, the class-map does not match any packets. What is the most likely reason?
3A network engineer is designing a QoS policy for a Cisco router that connects to an MPLS VPN. The service provider expects all traffic to be marked with IP Precedence values. The engineer wants to ensure that voice traffic (DSCP EF) is mapped to IP Precedence 5. What configuration is required on the router to perform this mapping?
4A company is implementing QoS on its campus network. The network engineer configures a policy-map that sets the CoS value for voice traffic to 5 on a switch interface. However, when the traffic reaches the router, the CoS marking is lost. What is the most likely reason?
5A network engineer is troubleshooting voice quality issues on a WAN link. The engineer notices that voice packets are being dropped during congestion. The QoS policy uses LLQ for voice traffic, but the priority queue is not providing the expected bandwidth. What is the most likely cause?
6An enterprise is deploying QoS across a network that includes both Cisco and non-Cisco devices. The engineer wants to use a marking scheme that is end-to-end and not stripped at Layer 3 boundaries. Which marking field should the engineer use?
7A network engineer is configuring QoS on a Cisco router to prioritize business-critical applications. The engineer creates a class-map that matches traffic based on the destination IP address and port. However, the class-map does not match the expected traffic. What is the most likely reason?
8A network engineer is configuring QoS on a Cisco switch to ensure that video traffic (DSCP AF41) is not dropped during congestion. The engineer creates a policy-map that sets the queue-limit for the AF41 class. However, the switch is still dropping video packets. What is the most likely cause?
9A network engineer is implementing QoS on a Cisco router that connects to a service provider. The provider uses MPLS and expects the MPLS EXP bits to be set for voice traffic. The engineer configures a policy-map that sets the MPLS EXP to 5. However, the provider reports that the EXP bits are not being set. What is the most likely reason?
10An architect is designing a QoS policy for a campus LAN that must support real-time voice and video traffic alongside mission-critical data. The design must use the DiffServ model with consistent per-hop behavior across all switches. Which approach should the architect choose to ensure that voice traffic receives priority queuing while video traffic is guaranteed bandwidth without starving other classes?
11A network team is designing QoS for a Cisco SD-WAN fabric connecting multiple branch offices to a central data center. The design must ensure that VoIP traffic from branch sites receives priority treatment across the WAN overlay, regardless of the underlying transport (MPLS, Internet, LTE). Which architectural component should the team configure to enforce consistent QoS policies across all WAN edges?
12An enterprise is deploying a leaf-spine architecture in its data center to support high-bandwidth east-west traffic. The design must include QoS to prioritize storage replication traffic (iSCSI) over backup traffic, while ensuring low latency for real-time applications. Where should the architect apply QoS classification and queuing policies in this topology?
13A company is virtualizing its network functions using NFV on a KVM-based hypervisor. The design must ensure that the virtual router (CSR1000v) can handle high-throughput traffic with minimal latency. Which architectural consideration is most critical for achieving this goal?
14An architect is designing a QoS policy for a Cisco SD-Access fabric. The policy must prioritize voice traffic from wireless clients connected to fabric-enabled access points over other traffic types. The design should use the fabric's built-in capabilities to simplify deployment. Which approach should the architect take?
15A network team is designing QoS for a multi-tenant data center using leaf-spine architecture. Each tenant requires guaranteed bandwidth for their mission-critical applications, while best-effort traffic must not interfere. The design must use hierarchical queuing to enforce per-tenant fairness. Which queuing mechanism should the architect implement on the leaf switches?
16An enterprise is designing a QoS architecture for its WAN edge routers connecting to multiple service providers. The design must support traffic shaping to avoid packet drops due to provider policers, while also prioritizing real-time traffic. Which approach should the architect use to shape traffic to the contracted CIR while still allowing bursts?
17A network architect is designing QoS for a Cisco SD-WAN deployment that uses a mix of MPLS and broadband Internet transports. The design must ensure that interactive video traffic is not delayed by large file transfers, even when the Internet link experiences congestion. Which SD-WAN policy type should the architect use to enforce this behavior?
18A company is deploying a new campus network with a hierarchical design (core, distribution, access). The QoS design must ensure that voice traffic is prioritized end-to-end, and that marking is trusted only on access ports connected to IP phones. Which architectural approach should the architect take for classification and marking?
19Consider the following configuration snippet: policy-map QOS_POLICY class VOICE priority percent 30 class VIDEO bandwidth percent 20 queue-limit 50 packets class class-default fair-queue queue-limit 100 packets What is the effect of this configuration?
20Given the following configuration: interface GigabitEthernet0/1 service-policy output QOS_POLICY Which statement is true about applying a service-policy in the output direction?
21Consider the following configuration: class-map match-any VOICE match ip dscp ef class-map match-any VIDEO match ip dscp af41 match ip dscp af42 What is the effect of the match-any keyword in these class-maps?
22Examine the following configuration: policy-map SHAPE_POLICY class class-default shape average 10000000 service-policy INNER_POLICY What is the purpose of the nested service-policy (service-policy INNER_POLICY) under the shape command?
23Given the following configuration: policy-map MARKING_POLICY class CRITICAL_DATA set dscp af31 class BULK_DATA set dscp af11 class class-default set dscp default What is the effect of the set dscp default command in the class-default?
24Consider the following configuration: policy-map QUEUE_POLICY class VOICE priority level 1 police cir 1000000 class VIDEO priority level 2 police cir 2000000 class class-default fair-queue What is the effect of using priority level 1 and priority level 2?
25What is the default CoS-to-queue mapping on a Cisco switch that supports QoS?
26Which QoS mechanism is used to prevent congestion by dropping packets before a queue becomes full?
27What is the purpose of the 'police' command in a QoS policy-map?
28Drag and drop the steps of the DiffServ traffic classification and marking pipeline into the correct order, from first to last.
29Drag and drop the steps of the QoS trust boundary configuration process into the correct order, from first to last.
30Drag and drop the steps of the QoS shaping and policing configuration sequence into the correct order, from first to last.
31Drag and drop the steps of DSCP re-marking at enterprise WAN edge into the correct order, from first to last.
32Drag and drop the steps of traffic shaping vs policing configuration steps into the correct order, from first to last.
33Drag and drop the steps of LLQ configuration for voice traffic into the correct order, from first to last.
34Drag and drop the steps of WRED configuration for TCP congestion avoidance into the correct order, from first to last.
35Drag and drop the steps of NBAR2 application recognition and classification steps into the correct order, from first to last.
36Drag and drop each DSCP value on the left to its matching Per-Hop Behavior (PHB) on the right.
37Drag and drop each QoS model on the left to its matching characteristic on the right.
38Drag and drop each CoS value on the left to its matching traffic type on the right.
39Drag and drop each queuing mechanism on the left to its matching use case on the right.
40Drag and drop each MQC component on the left to its matching role on the right.
41Drag and drop the steps of DSCP re-marking at enterprise WAN edge into the correct order, from first to last.
42Drag and drop the steps of traffic shaping vs policing configuration steps into the correct order, from first to last.
43Drag and drop the steps of LLQ configuration for voice traffic into the correct order, from first to last.
44Drag and drop the steps of WRED configuration for TCP congestion avoidance into the correct order, from first to last.
45Drag and drop the steps of NBAR2 application recognition and classification steps into the correct order, from first to last.
46Drag and drop each DSCP value on the left to its matching Per-Hop Behavior (PHB) on the right.
47Drag and drop each QoS model on the left to its matching characteristic on the right.
48Drag and drop each CoS value on the left to its matching traffic type on the right.
49Drag and drop each queuing mechanism on the left to its matching use case on the right.
50Drag and drop each MQC component on the left to its matching role on the right.
51Which two statements about the QoS trust boundary on a Cisco switch are true? (Choose two.)
52Which three statements about classification and marking in a QoS architecture are true? (Choose three.)
53Which two statements about policing and shaping in a QoS architecture are true? (Choose two.)
54Which three statements about queuing and congestion avoidance in a QoS architecture are true? (Choose three.)
55Which two statements about the Cisco QoS trust boundary are true? (Choose two.)
56Which two statements about Cisco QoS classification and marking are true? (Choose two.)
57Which three statements about Cisco QoS queuing and scheduling are true? (Choose three.)
58Which three statements about Cisco QoS policing and shaping are true? (Choose three.)
The QoS Architecture domain covers the key concepts tested in this area of the 350-401 exam blueprint published by Cisco. Courseiva provides free domain-focused practice, mock exams, missed-question review, and readiness tracking across all 350-401 domains — no account required.
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