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graph TB
subgraph "IoT Devices (UE)"
DEV1["Smartphones"]
DEV2["NB-IoT Sensors"]
DEV3["LTE-M Trackers"]
end
subgraph "RAN (Radio Access Network)"
BS["Base Station<br/>eNodeB (4G)<br/>gNB (5G)"]
end
subgraph "EPC (Evolved Packet Core)"
MME["MME<br/>Mobility<br/>Management"]
SGW["S-GW<br/>Serving<br/>Gateway"]
PGW["P-GW<br/>PDN<br/>Gateway"]
HSS["HSS<br/>Subscriber<br/>Database"]
end
INTERNET["Internet"]
subgraph "IoT Cloud"
CLOUD1["MQTT Broker"]
CLOUD2["CoAP Server"]
CLOUD3["HTTPS API"]
end
DEV1 & DEV2 & DEV3 -->|LTE/5G/NB-IoT Radio| BS
BS --> MME
BS --> SGW
MME --> HSS
MME --> SGW
SGW --> PGW
PGW --> INTERNET
INTERNET --> CLOUD1 & CLOUD2 & CLOUD3
style DEV1 fill:#E67E22,stroke:#2C3E50,color:#fff
style DEV2 fill:#E67E22,stroke:#2C3E50,color:#fff
style DEV3 fill:#E67E22,stroke:#2C3E50,color:#fff
style BS fill:#16A085,stroke:#2C3E50,color:#fff
style MME fill:#16A085,stroke:#2C3E50,color:#fff
style SGW fill:#16A085,stroke:#2C3E50,color:#fff
style PGW fill:#16A085,stroke:#2C3E50,color:#fff
style HSS fill:#16A085,stroke:#2C3E50,color:#fff
style INTERNET fill:#2C3E50,stroke:#16A085,color:#fff
style CLOUD1 fill:#2C3E50,stroke:#16A085,color:#fff
style CLOUD2 fill:#2C3E50,stroke:#16A085,color:#fff
style CLOUD3 fill:#2C3E50,stroke:#16A085,color:#fff
821 Cellular Network Architecture for IoT
821.1 Learning Objectives
By the end of this chapter, you will be able to:
- Understand Cellular Architecture: Explain the components of LTE/5G networks and how IoT traffic flows
- Select Cellular IoT Technologies: Choose between NB-IoT, LTE-M, and 5G profiles based on requirements
- Analyze Mobility Requirements: Determine when handover support is critical for your application
- Compare Core Network Functions: Understand the roles of MME, S-GW, P-GW, and HSS in IoT connectivity
821.2 Prerequisites
Required Chapters: - Mobile Wireless Technologies Basics - Core concepts - Cellular IoT Fundamentals - Cellular technologies - Networking Fundamentals - Basic networking
Technical Background: - Cellular generations (2G, 3G, 4G, 5G) - Frequency spectrum concepts - Handoff and roaming basics
Estimated Time: 30 minutes
TipFor Beginners: Understanding Cellular Networks
What is cellular architecture? Cellular networks divide geographic areas into “cells” served by base stations. When your phone moves between cells, the network hands off the connection seamlessly.
Why does it matter for IoT? IoT devices using cellular connectivity (NB-IoT, LTE-M, 5G) rely on this architecture for coverage, but many IoT devices are stationary and don’t need full mobility support.
Key Terms: - UE (User Equipment): Your IoT device - eNodeB/gNB: The cell tower/base station - EPC (Evolved Packet Core): The “brain” of the cellular network - MME: Manages device connections and mobility
821.3 Cellular Network Architecture Overview
Understanding how mobile cellular networks route IoT traffic is essential for deployment planning.
821.3.1 LTE/4G Architecture for IoT
The LTE architecture consists of three main domains: the User Equipment (UE), the Radio Access Network (RAN), and the Evolved Packet Core (EPC). IoT devices connect through the radio interface to base stations (eNodeBs), which then connect to the core network for routing to the internet and cloud services.
821.3.2 Core Network Components
MME (Mobility Management Entity): The MME is the control plane component that handles device attachment, authentication, and mobility. For IoT devices, the MME manages:
- Device registration and deregistration
- Security procedures (authentication, encryption)
- Paging for incoming data when device is in sleep mode
- Handover control between cells (for mobile devices)
S-GW (Serving Gateway): The S-GW is the user plane anchor that routes data packets between the device and the internet. It:
- Buffers data during handover
- Collects charging information
- Routes packets to the correct P-GW
P-GW (PDN Gateway): The P-GW connects the cellular network to external IP networks (the internet). It:
- Assigns IP addresses to devices
- Performs policy enforcement
- Handles QoS for different traffic types
HSS (Home Subscriber Server): The HSS stores subscriber information including:
- Device identity (IMSI)
- Service subscriptions
- Authentication credentials (for SIM-based authentication)
821.3.3 IoT-Specific Optimizations
Cellular IoT technologies (NB-IoT and LTE-M) include optimizations for low-power, infrequent transmissions:
Power Saving Mode (PSM): Devices can enter deep sleep for extended periods (hours to days) while maintaining network registration. The network doesn’t page the device during PSM, dramatically reducing power consumption.
Extended Discontinuous Reception (eDRX): Devices negotiate longer sleep cycles between paging opportunities. Instead of waking every few seconds, devices can sleep for minutes, saving battery while remaining reachable.
Control Plane CIoT EPS Optimization: Small data payloads (up to ~1500 bytes) can be sent through the control plane (signaling channel) without establishing a full data bearer. This reduces latency and power for small, infrequent transmissions.
821.4 Cellular IoT Technology Selection
Choosing the right cellular IoT technology depends on mobility, coverage, data rate, and latency requirements.
TipDecision Framework: Cellular IoT Technology Selection
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flowchart TD
START([Cellular IoT<br/>Selection]) --> Q1{Device<br/>mobile?}
Q1 -->|Yes - Moves| Q2{Need<br/>voice?}
Q1 -->|No - Fixed| Q3{Deep indoor<br/>coverage?}
Q2 -->|Yes| LTEM[LTE-M<br/>Asset tracking<br/>Wearables, Voice]
Q2 -->|No| Q4{Data rate<br/>needed?}
Q3 -->|Yes| NBIOT[NB-IoT<br/>Basements, meters<br/>10+ year battery]
Q3 -->|No| Q4
Q4 -->|<100 kbps| NBIOT
Q4 -->|100 kbps - 1 Mbps| LTEM
Q4 -->|>1 Mbps| Q5{Latency<br/>critical?}
Q5 -->|Yes <10ms| URLLC[5G URLLC<br/>Industrial control<br/>V2X, Robotics]
Q5 -->|No| EMBB[5G eMBB<br/>Video streaming<br/>AR/VR]
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821.4.1 NB-IoT (Narrowband IoT)
Best For: Stationary sensors with small, infrequent payloads requiring deep indoor penetration.
| Characteristic | Value |
|---|---|
| Data Rate | Up to 250 kbps (typical: 20-60 kbps) |
| Latency | 1.5-10 seconds (depending on PSM/eDRX) |
| Coverage | +20 dB link budget gain (basement, underground) |
| Battery Life | 10+ years on AA batteries (with PSM) |
| Mobility | Stationary or very low mobility |
| Voice | Not supported |
Use Cases: - Smart meters (electricity, gas, water) - Underground parking sensors - Basement environmental monitors - Agricultural soil sensors
821.4.2 LTE-M (Cat-M1)
Best For: Mobile devices requiring higher data rates, voice support, and full handover.
| Characteristic | Value |
|---|---|
| Data Rate | Up to 1 Mbps |
| Latency | 10-15 ms (connected mode) |
| Coverage | +15 dB link budget gain |
| Battery Life | 5-10 years (with PSM/eDRX) |
| Mobility | Full handover support |
| Voice | VoLTE supported |
Use Cases: - Asset tracking (vehicles, containers) - Wearables with emergency calling - Point-of-sale terminals - Connected health devices
821.4.3 5G IoT Profiles
5G introduces multiple service categories with different IoT applicability:
eMBB (Enhanced Mobile Broadband): High bandwidth for video streaming, AR/VR. Typically not battery-constrained.
URLLC (Ultra-Reliable Low-Latency Communication): Sub-10ms latency for industrial control, V2X, robotics. Requires power for continuous connectivity.
mMTC (Massive Machine-Type Communication): Evolved from NB-IoT/LTE-M concepts. High device density, low power.
821.5 Mobile Technology Evolution
Understanding the evolution of cellular technology helps contextualize IoT options.
| Generation | Technology | Data Rate | IoT Relevance |
|---|---|---|---|
| 2G | GSM, GPRS | tens of kbps (GPRS) | Legacy M2M (sunsetting) |
| 3G | UMTS, HSPA | Mbps peak (HSPA) | Early IoT (sunsetting) |
| 4G | LTE, LTE-A | 10s-100s Mbps peak | Current IoT (LTE-M/NB-IoT) |
| 5G | NR | 100s Mbps-Gbps peak | Emerging IoT (profile-dependent) |
WarningNetwork Sunset Considerations
2G and 3G networks are being decommissioned globally. New IoT deployments should use:
- NB-IoT for stationary, low-data applications
- LTE-M for mobile applications or higher data rates
- 5G only if specific features (URLLC, slicing) are required
Check carrier timelines in your deployment region before selecting technology.
821.6 Cellular vs. LPWAN Comparison
When planning IoT deployments, compare cellular options with unlicensed LPWAN alternatives.
| Factor | Cellular (NB-IoT/LTE-M) | LoRaWAN/Sigfox |
|---|---|---|
| Spectrum | Licensed (operator-managed) | Unlicensed ISM bands |
| Coverage | Carrier-dependent | Self-deployed gateways |
| QoS | Managed, with SLAs possible | Best-effort, shared spectrum |
| Recurring Cost | Per-device subscription | Gateway infrastructure |
| Battery Life | 5-10+ years | 5-10+ years |
| Mobility | Full handover (LTE-M) | Limited |
| Data Rate | Higher (250 kbps - 1 Mbps) | Lower (0.3-50 kbps) |
TipSensor Squad Says: Cellular Networks Explained!
Sammy Sensor: “Think of cellular networks like a pizza delivery system!”
Lila the Light Sensor: “The cell tower is like the pizza shop - it covers a neighborhood. When you order (send data), they deliver to your house (the cloud)!”
Max the Motion Detector: “And if you’re driving while ordering, the system transfers your order to the next pizza shop along your route - that’s handover!”
Bella the Button: “NB-IoT devices are like ordering just garlic bread - small order, but they’ll deliver to your basement! LTE-M is like ordering a whole feast - bigger delivery, and they’ll follow your car!”
821.7 Summary
This chapter covered the fundamental architecture of cellular networks for IoT:
Key Concepts: - Cellular architecture includes UE (devices), RAN (base stations), and EPC (core network) - The MME handles mobility and control, while S-GW and P-GW route data - IoT-specific optimizations (PSM, eDRX) enable multi-year battery life
Technology Selection: - NB-IoT: Deep indoor, stationary, low data rate, 10+ year battery - LTE-M: Mobile, higher data rate, voice support, full handover - 5G: High bandwidth (eMBB) or ultra-low latency (URLLC)
Design Considerations: - Licensed spectrum provides managed QoS but requires subscriptions - Check carrier coverage and network sunset timelines - Match technology to mobility, data rate, and coverage requirements
821.8 What’s Next
Continue your mobile wireless review with:
- Scenario-Based Understanding: Practice trade-off reasoning with real deployment scenarios
- Comprehensive Quiz: Test your knowledge with challenging questions
- Cellular IoT Fundamentals: Deep dive into NB-IoT and LTE-M