1. Introduction

Selecting the appropriate UART-based RF module requires careful consideration of baud rate compatibility, transmission distance, power consumption, and environmental factors. EBYTE offers a diverse portfolio of UART RF modules, ranging from low-power short-range solutions to high-power long-range systems, each designed for specific applications.

This guide examines the key selection criteria, including:

  • Baud rate matching between UART and RF interfaces

  • Communication distance requirements

  • Interference resilience in noisy environments

  • Power efficiency for battery-operated devices

2. Baud Rate Matching: Ensuring Seamless Serial Communication

2.1 Understanding Baud Rate in UART RF Modules

EBYTE's UART RF modules support a wide range of baud rates (from 1.2kbps to 1Mbps), allowing compatibility with various microcontrollers and serial devices.

Key Modules & Their Baud Rate Capabilities:

Module Series

Supported Baud Rates

Typical Applications

E32 Series

1.2kbps - 115.2kbps

Industrial sensors, remote monitoring

E22 Series

2.4kbps - 62.5kbps

Smart metering, agricultural IoT

E70 Series

9.6kbps - 921.6kbps

High-speed telemetry, drone control

E28 Series (2.4GHz)

2400bps - 1Mbps

Real-time control systems

Best Practices for Baud Rate Selection:

✔ Match MCU & module baud rates (e.g., 9600bps for Arduino compatibility)
✔ Higher baud rates for time-sensitive applications (e.g., robotics)
✔ Lower baud rates for long-range, low-power scenarios (e.g., LoRa networks

3. Communication Distance: Choosing the Right Range

3.1 Factors Affecting Wireless Range

  • Frequency band (433MHz vs. 868/915MHz vs. 2.4GHz)

  • Transmit power (10dBm to 33dBm options)

  • Antenna design (PCB vs. external antenna)

  • Environmental obstacles (urban vs. rural deployments)

3.2 EBYTE Module Recommendations by Range

Range Requirement

Recommended Module

Max Distance

Key Features

Short-range (0-300m)

E28-2G4M20S (2.4GHz)

300m

High-speed, low-latency

Medium-range (1-5km)

E32-433T30D (433MHz)

5km

LoRa modulation, 30dBm power

Long-range (5-10km+)

E22-900T33S (915MHz)

10km

Long-range LoRa, 33dBm PA

Case Study:

A smart agriculture system using E32-433T20D modules achieved 3km line-of-sight communication at 9600bps, with <0.1% packet loss in open fields.

4. Environmental Considerations & Interference Mitigation

4.1 Dealing with RF Interference

EBYTE modules integrate multiple anti-interference technologies:

  • LoRa Spread Spectrum (E22/E32 series) – Resists narrowband noise

  • Frequency Hopping (FHSS) (E62 series) – Avoids congested channels

  • FEC (Forward Error Correction) – Corrects errors without retransmission

4.2 Industrial vs. Urban Deployments

Environment

Challenge

Recommended Solution

Industrial

EMI from motors

E62-433T20D (FHSS)

Urban

WiFi/Bluetooth congestion

E28-2G4M20S (2.4GHz DFS)

Suburban

Multipath fading

E32-868T30S (LoRa + FEC)

5. Power Efficiency & Battery Life Optimization

5.1 Comparing Power Consumption

Module

TX Current

RX Current

Sleep Current

E22-400T20S

120mA (@20dBm)

15mA

2µA

E32-433T30D

450mA (@30dBm)

25mA

5µA

E70-900T20S

90mA (@20dBm)

12mA

1µA

Tip: Use air wake-up (E22 series) to extend battery life in IoT sensors

Selecting the Optimal EBYTE UART RF Module

Quick Selection Guide:

  1. Define baud rate needs → Match with module capabilities

  2. Estimate required range → Choose frequency & power level

  3. Assess environmental noise → Apply FHSS/LoRa if needed

  4. Optimize power usage → Select low-power modes for battery devices

EBYTE’s UART RF modules provide flexible solutions for industrial automation, smart cities, agriculture, and consumer IoT. By carefully evaluating baud rate, range, and environmental factors, engineers can ensure reliable wireless communication in any application.