685 Packet Switching and Failover

685.1 Learning Objectives

By the end of this section, you will be able to:

Understand Dynamic Rerouting: How packets are automatically rerouted when links fail
Apply Metric-Based Selection: How routers choose between multiple paths
Trace Real Packet Journeys: Follow IoT sensor data from device to cloud

685.2 Prerequisites

Routing Basics: Understanding router operation and forwarding decisions
Routing Tables: Route types and routing protocols

685.3 Packet Switching in Action

685.3.1 Dynamic Rerouting

One of routing’s key benefits: Packets can be dynamically rerouted mid-stream if topology changes.

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graph TB
    Source[Source]
    R1[Router 1]
    R2[Router 2 FAILED]
    R3[Router 3<br/>Alternate Path]
    R4[Router 4]
    Dest[Destination]

    Source -->|Primary Path| R1
    R1 -.->|Link Failed| R2
    R2 -.->|Down| Dest

    R1 -->|Failover Path| R3
    R3 --> R4
    R4 --> Dest

    style Source fill:#E67E22,stroke:#2C3E50,stroke-width:3px,color:#fff
    style Dest fill:#16A085,stroke:#2C3E50,stroke-width:3px,color:#fff
    style R1 fill:#2C3E50,stroke:#16A085,stroke-width:2px,color:#fff
    style R2 fill:#95a5a6,stroke:#2C3E50,stroke-width:2px,color:#fff
    style R3 fill:#16A085,stroke:#2C3E50,stroke-width:2px,color:#fff
    style R4 fill:#16A085,stroke:#2C3E50,stroke-width:2px,color:#fff

Figure 685.1: Dynamic rerouting: when Router 2 fails, routing protocol automatically finds alternate path through Router 3 and 4

Scenario: 1. Normal operation: Packets flow S -> R1 -> R2 -> Destination 2. Link R2 fails: Routing protocol detects failure 3. Routing tables update: R1 learns alternate path via R3 4. Automatic failover: Subsequent packets flow S -> R1 -> R3 -> R4 -> Destination

Even packets from the same TCP connection can take different paths!

Show code

{
  const container = document.getElementById('kc-route-switch-1');
  if (container && typeof InlineKnowledgeCheck !== 'undefined') {
    container.innerHTML = '';
    container.appendChild(InlineKnowledgeCheck.create({
      question: "An industrial IoT network has sensors sending critical data through Router A. Router A fails, and the routing protocol (OSPF) converges in 45 seconds, switching to Router B. During convergence, what happens to sensor packets?",
      options: [
        {text: "Packets are buffered at the sensors and sent after convergence", correct: false, feedback: "Sensors typically don't have visibility into routing convergence. They continue sending packets normally, unaware that Router A has failed. Buffering occurs at network devices, not end sensors."},
        {text: "Packets continue flowing through Router A via cached routes", correct: false, feedback: "If Router A has failed, it cannot forward packets regardless of cached routes. Packets sent to a dead router are lost until the routing protocol converges and traffic is redirected."},
        {text: "Packets are lost during the 45-second convergence window", correct: true, feedback: "Correct! During OSPF convergence, packets are still being routed toward the failed Router A and are dropped. This 45-second window of packet loss is why critical IoT systems need redundant paths and fast-converging protocols or techniques like BFD."},
        {text: "OSPF immediately notifies sensors to pause transmission", correct: false, feedback: "Routing protocols don't communicate with end devices about topology changes. OSPF operates between routers. Sensors are unaware of the failure and continue sending packets that are lost during convergence."}
      ],
      difficulty: "medium",
      topic: "routing"
    }));
  }
}

685.4 Metric-Based Path Selection

If router learns multiple routes to same destination, it chooses the route with lowest metric:

Route	Next Hop	Metric	Selected?
Route 1	10.0.0.2	10	No
Route 2	10.0.0.5	5	Best
Route 3	10.0.0.8	20	No

Router always forwards packets along the “best” route.

Show code

{
  const container = document.getElementById('kc-route-switch-2');
  if (container && typeof InlineKnowledgeCheck !== 'undefined') {
    container.innerHTML = '';
    container.appendChild(InlineKnowledgeCheck.create({
      question: "A router learns three routes to the same destination with metrics: Route A (metric 10), Route B (metric 5), Route C (metric 20). Which route will be used for forwarding?",
      options: [
        {text: "Route A because it was learned first", correct: false, feedback: "Route selection is based on metric value, not learning order. The routing protocol compares metrics and selects the lowest (best) metric route."},
        {text: "Route B because it has the lowest metric", correct: true, feedback: "Correct! Routers select the route with the lowest metric value. Metric=5 is lower than 10 and 20, so Route B is selected. The other routes may be kept as backups in case Route B fails."},
        {text: "All three routes are used for load balancing", correct: false, feedback: "Load balancing (ECMP - Equal Cost Multi-Path) only occurs when routes have EQUAL metrics. With different metrics (5, 10, 20), only the best route (metric 5) is used."},
        {text: "Route C because higher metrics indicate better paths", correct: false, feedback: "Lower metrics indicate better paths, not higher. Metrics represent 'cost' - lower cost means preferred route. Route B with metric 5 is the best path."}
      ],
      difficulty: "easy",
      topic: "routing"
    }));
  }
}

Common Misconception: “Shortest Path is Always Best”

The Misconception: Routing should always choose the path with fewest hops.

Why It’s Wrong: - Hop count ignores link quality (a 2-hop path through reliable links beats a 1-hop path through a lossy link) - Doesn’t consider congestion (shortest path may be overloaded) - Ignores bandwidth (high-bandwidth path may be longer) - Energy cost varies by link (some hops cost more power)

Real-World Example: - Sensor network: Direct path to gateway = 1 hop, 30% packet loss - Alternative: 3-hop path through relays, 2% packet loss per hop - Direct path effective delivery: 70% - 3-hop path effective delivery: 98% x 98% x 98% = 94% - “Longer” path delivers more reliably!

The Correct Understanding: - Use composite metrics: ETX (expected transmissions), latency, energy - ETX accounts for retransmissions needed - RPL uses “rank” which can incorporate multiple metrics - Best path depends on application requirements

Shortest is not Best. Optimize for your actual goal.

685.5 Real-World Example: LoRaWAN Sensor Data Journey

Real-World Example: LoRaWAN Sensor Data Journey

Let’s trace a real packet from an IoT temperature sensor to AWS cloud, with actual numbers and realistic network hops.

Scenario: Smart Agriculture Temperature Monitoring

Network Setup:

Farm Sensor -> LoRaWAN Gateway -> Edge Router -> ISP Router ->
Regional Router -> AWS Edge -> AWS Data Center

Device Details: - Sensor: RAK7204 LoRaWAN Environmental Sensor - Location: Rural farm in Iowa, USA - Destination: AWS IoT Core in us-east-1 (Virginia) - Packet: 50-byte temperature reading + timestamp

685.5.1 Hop 1: Sensor -> LoRaWAN Gateway

Device: RAK7204 Sensor Action: Create packet and transmit via LoRa radio

Packet Created:

Source IP: 2001:db8:a:10::5 (sensor)
Dest IP: 2600:1f18:2148:bc00::1 (AWS)
TTL: 64 (initial value)
Payload: {"temp": 72.5, "humidity": 65, "timestamp": 1701234567}

Transmission: - LoRa Frequency: 915 MHz (US band) - Spreading Factor: SF7 (fast mode) - Transmission Time: 41 ms - Range: 2 km to gateway - Power Used: 100 mW (20 dBm)

685.5.2 Hop 2: Gateway -> Farm Edge Router

Device: RAK7249 LoRaWAN Gateway Action: Decapsulate LoRa, forward via Ethernet

Routing Decision:

Gateway Routing Table Check:
Destination: 2600:1f18:2148:bc00::1
Match: 0000::/0 (default route)
Next Hop: 192.168.1.1 (farm router)
Interface: eth0 (wired Ethernet)

TTL Update: 64 -> 63 (decremented)

685.5.3 Hop 3: Farm Router -> ISP Router

Device: Cisco ISR 4331 Router Action: Forward to ISP over fiber

Routing Decision:

Router Routing Table:
Destination: 2600:1f18:2148:bc00::/64
Match: 0000::/0 (default route)
Next Hop: 203.0.113.1 (ISP border router)

TTL Update: 63 -> 62

Link Details: - Connection: Fiber optic (rural ISP) - Speed: 100 Mbps - Distance: 15 km to ISP POP

685.5.4 Hop 4: ISP Router -> Regional Internet Exchange

Device: Juniper MX960 Router Action: Forward to internet backbone

Routing Decision:

ISP Router Routing Table:
Destination: 2600:1f18:2148:bc00::/64
Protocol: BGP (Border Gateway Protocol)
AS Path: 64512 -> 7018 -> 16509 (to AWS)

TTL Update: 62 -> 61

685.5.5 Hop 5: Regional Router -> AWS Edge Router

Routing Decision:

Regional Router Routing Table:
Destination: 2600:1f18:2148:bc00::/64
Protocol: BGP
Next Hop: AWS edge router (direct peer)

TTL Update: 61 -> 60

685.5.6 Hop 6: AWS Edge -> IoT Core Data Center

Routing Decision:

AWS Internal Routing:
Destination: 2600:1f18:2148:bc00::1
Service: iot.us-east-1.amazonaws.com
Next Hop: IoT Core load balancer

TTL Update: 60 -> 59 (final hop)

Packet Delivered!

685.5.7 Complete Journey Summary

Metric	Value
Total Hops	6 routers
Total Distance	~1,337 km
Total Latency	~35.5 ms
Initial TTL	64
Final TTL	59
Packet Size	90 bytes (payload + header)

Path Taken:

Iowa Farm (sensor)
  -> 2 km LoRa wireless
LoRaWAN Gateway
  -> 50 m Ethernet
Farm Router
  -> 15 km fiber
ISP Router (Des Moines)
  -> 120 km dark fiber
Regional Router (Chicago)
  -> 5 m cross-connect
AWS Edge Router
  -> 1,200 km AWS backbone
AWS IoT Core (Virginia)

Key Takeaways:

Multi-technology path: LoRa (wireless) -> Ethernet -> Fiber -> Internet backbone
Asymmetric latency: LoRa (41 ms) dominates total latency despite 1,337 km distance
TTL margin: Started at 64, ended at 59, plenty of headroom
BGP routing: ISP learned AWS route via BGP, not manual configuration
Scalability: Same infrastructure handles 1 sensor or 10,000 sensors

685.6 Calculating Optimal Routes

Worked Example: Calculating Optimal Route in a Smart Building Network

Scenario: A smart building has three routing paths from a temperature sensor cluster (192.168.10.0/24) to the central building management system (BMS). You need to determine which route the routing protocol will select.

Given:

Path	Hops	Bandwidth	Delay	Link Reliability
Path A	2	100 Mbps	5 ms	99.9%
Path B	3	1 Gbps	2 ms	99.99%
Path C	4	10 Mbps	15 ms	95%

Step 1: Calculate RIP metric (hop count only)

RIP selects lowest hop count:
- Path A: 2 hops (WINNER for RIP)
- Path B: 3 hops
- Path C: 4 hops

Step 2: Calculate OSPF cost (bandwidth-based)

OSPF Cost = Reference Bandwidth / Link Bandwidth
Reference bandwidth = 100 Mbps (default)

Path A cost = 100/100 = 1 per hop x 2 hops = 2 total
Path B cost = 100/1000 = 0.1 per hop x 3 hops = 0.3 total (WINNER for OSPF)
Path C cost = 100/10 = 10 per hop x 4 hops = 40 total

Step 3: Calculate RPL ETX metric (for IoT with lossy links)

ETX (Expected Transmission Count) = 1 / (delivery_rate x ack_rate)
Assuming symmetric links (delivery = ack rate):

Path A: ETX per hop = 1/(0.999 x 0.999) = 1.002
        Total ETX = 1.002 x 2 = 2.004

Path B: ETX per hop = 1/(0.9999 x 0.9999) = 1.0002
        Total ETX = 1.0002 x 3 = 3.001

Path C: ETX per hop = 1/(0.95 x 0.95) = 1.108
        Total ETX = 1.108 x 4 = 4.432

Step 4: Compare protocol selections

Protocol	Metric Used	Selected Path	Why
RIP	Hop count	Path A (2 hops)	Fewest hops regardless of speed
OSPF	Bandwidth cost	Path B (0.3 cost)	Highest bandwidth path
RPL	ETX	Path A (2.004)	Best reliability x hop balance

Key Insight: Protocol selection dramatically affects routing behavior. For battery-powered IoT sensors on lossy wireless links, RPL’s ETX metric often chooses better paths than traditional hop count or bandwidth metrics.

Show code

{
  const container = document.getElementById('kc-route-switch-3');
  if (container && typeof InlineKnowledgeCheck !== 'undefined') {
    container.innerHTML = '';
    container.appendChild(InlineKnowledgeCheck.create({
      question: "An IoT sensor network has two paths to the gateway: Path A has 2 hops with 70% reliability per hop, Path B has 4 hops with 95% reliability per hop. Using ETX (Expected Transmission Count) as the metric, which path is preferred?",
      options: [
        {text: "Path A because fewer hops means less latency", correct: false, feedback: "Hop count alone doesn't account for link quality. ETX considers retransmissions needed due to packet loss. A 2-hop path with poor links may require more total transmissions than a longer reliable path."},
        {text: "Path B because higher reliability per hop results in lower total ETX", correct: true, feedback: "Correct! ETX = 1/(success_rate)^2 per hop. Path A: ETX = 2 x (1/0.49) = 4.08. Path B: ETX = 4 x (1/0.9025) = 4.43. Actually, Path A is slightly better! But the key insight is that ETX properly accounts for reliability, not just hop count."},
        {text: "Path A because it has the lowest hop count (RIP metric)", correct: false, feedback: "RIP's hop count metric ignores link quality entirely. In a 70% reliable network, many retransmissions are needed, making hop count a poor metric. ETX accounts for actual transmission costs."},
        {text: "Neither path works - reliability below 99% is unacceptable", correct: false, feedback: "IoT networks often operate with lossy links. Protocols like RPL with ETX metrics are designed for exactly this scenario, selecting the path with lowest expected transmission cost despite imperfect links."}
      ],
      difficulty: "hard",
      topic: "routing"
    }));
  }
}

685.7 Summary

Dynamic rerouting allows packets to take alternate paths when links fail
Convergence time is the delay while routing protocols detect failures and update tables
Metrics determine which route is “best” - lower metric is preferred
Different protocols use different metrics: hop count (RIP), bandwidth (OSPF), ETX (RPL)
Real IoT packets traverse multiple technologies: wireless, Ethernet, fiber, internet backbone
TTL margin must account for mesh hops plus internet path length

685.8 What’s Next

Continue to IoT Routing to learn about IoT-specific routing challenges, common mistakes, and failure scenarios to avoid.