In the world of Internet of Things (IoT), connectivity often means compromise. Wi‑Fi and Bluetooth offer high bandwidth but short range. Cellular provides wide coverage but consumes significant power and requires ongoing subscription fees. For applications that need to send small amounts of data over kilometers — not meters — while running on a battery for years, LoRa radio modules have become the industry standard.
LoRa (Long Range) is a chirp spread spectrum (CSS) modulation technique developed by Semtech. Unlike traditional (G)FSK modulation that pushes a fixed carrier frequency up and down, LoRa spreads the signal across a wide bandwidth using frequency chirps. This spread‑spectrum approach delivers a processing gain that pushes receiver sensitivity down to -148 dBm, allowing signals to be decoded even when they are buried deep below the noise floor. In practical terms: a LoRa radio module can reliably communicate over 10–15 kilometers in open rural areas, penetrate dense urban infrastructure, and still sip battery power measured in microamps.
Coral RF has built an comprehensive portfolio of high‑performance LoRa radio modules around Semtech‘s SX1262 transceiver — the industry’s most advanced LoRa chipset. From low‑power end nodes to professional LoRaWAN gateways with up to 5 watts of output power, Coral RF provides the building blocks for any long‑range IoT deployment.
The Semtech SX1262 is the third‑generation LoRa transceiver, offering significant improvements over its predecessors (SX1276/SX1278). The SX1261 and SX1262 Sub‑GHz radio transceivers are ideal for long‑range wireless applications, designed for long battery life with just 4.2 mA of active receive current consumption across a continuous frequency coverage from 150 MHz to 960 MHz, supporting all major Sub‑GHz ISM bands worldwide. The SX1261 can transmit up to +15 dBm, while the SX1262 can transmit up to +22 dBm with highly efficient integrated power amplifiers.
Key differentiators of the SX1262:
| Parameter | SX1262 Value |
|---|---|
| RX Sensitivity | -148 dBm (LoRa, SF12) |
| Max Integrated PA | +22 dBm |
| RX Current | 4.2 – 10.1 mA |
| TX Current (native) | 32 – 118 mA |
| Supply Voltage | 1.8 – 3.7 V |
| Interface | SPI |
| Package | 4×4 mm QFN24 |
These devices support LoRa modulation for LPWAN use cases and (G)FSK modulation for legacy use cases, are highly configurable to meet different application requirements utilizing the global LoRaWAN standard or proprietary protocols, and comply with radio regulations including ETSI EN 300 220, FCC CFR 47 Part 15, China regulatory requirements, and Japanese ARIB T-108.
Coral RF extends the SX1262‘s native capabilities with external power amplifiers (PA) and low‑noise amplifiers (LNA), boosting output power to +27 dBm, +30 dBm, +33 dBm, and even +37 dBm — 5 watts of RF power — while maintaining the chip’s exceptional -148 dBm sensitivity. The result is a link budget exceeding 185 dB, enabling reliable communication over tens of kilometers in challenging non‑line‑of‑sight conditions.
Coral RF offers a full spectrum of LoRa modules based on the SX1262, ranging from low‑cost entry‑level transceivers to professional 5‑Watt gateway modules. All modules support LoRaWAN protocol for public and private IoT networks and expose all SX1262 pins for custom development.
The N401AS is Coral RF‘s most compact and cost‑effective LoRa radio module, designed for 169 MHz, 433 MHz, 868 MHz, and 915 MHz LoRa bands. It delivers up to +22 dBm output power with -148 dBm sensitivity, and the module leads all pins out of the SX1262 for secondary development, supporting LoRaWAN and Arduino.
| Parameter | N401AS |
|---|---|
| RF IC | Semtech SX1262 |
| Frequency Bands | 169 / 433 / 868 / 915 MHz |
| Max Output Power | +22 dBm |
| RX Sensitivity | -148 dBm (LoRa, typ.) |
| Symbol Rate | 0.3 – 62.5 kbps |
| Interface | SPI |
| Dimensions | 20 × 17 × 3 mm |
| Price | $3.80 |
The N401AS is ideal for battery‑powered sensors, low‑density IoT networks, and educational/prototyping projects where long range is required but maximum power is not necessary.
The N425AS boosts output power to +27 dBm (≈500 mW) while maintaining -148 dBm sensitivity, delivering robust performance at an optimized cost. It fully supports LoRaWAN for scalable IoT deployments, and lower peak TX current (800 mA) eases power supply design and extends battery life.
| Parameter | N425AS |
|---|---|
| RF IC | Semtech SX1262 + PA/LNA |
| Frequency Bands | 169 / 433 / 868 / 915 MHz, 1200 MHz |
| Max Output Power | +27 dBm |
| RX Sensitivity | -148 dBm (LoRa, typ.) |
| Interface | SPI |
| Dimensions | 30 × 21 × 3 mm |
| Price | $5.30 |
Applications include smart meters (water/gas/electricity), industrial and agricultural sensors, asset and logistics tracking, and smart city/building automation.
The N426AS pushes output power to +30 dBm (1 watt) with -148 dBm sensitivity, delivering robust performance at an optimized cost.
| Parameter | N426AS |
|---|---|
| RF IC | Semtech SX1262 + PA/LNA |
| Frequency Bands | 169 / 433 / 868 / 915 MHz, 1200 MHz |
| Max Output Power | +30 dBm (1W) |
| RX Sensitivity | -148 dBm (LoRa, typ.) |
| TX Current | ~500 mA (peak at +30 dBm) |
| Standby Current | 0.2 μA |
| Interface | SPI |
| Dimensions | 36 × 24 × 3 mm |
| Price | $6.00 |
The N426AS is fully supports LoRaWAN for scalable IoT deployments. It is cost‑optimized for medium‑range industrial sensors and private LoRa networks requiring reliable coverage.
The N427AS is a 2‑watt high‑power LoRa radio module that takes Semtech’s SX1262 and wraps it with a discrete power amplifier (PA) and a low‑noise amplifier (LNA). The result: you can transmit at +33 dBm (2 W) while still hearing signals down to -148 dBm. In plain English: it shouts loud enough to reach a gateway 15 km away in open country, and it listens softly enough to catch the faintest reply from a sensor at the edge of the farm.
| Parameter | N427AS |
|---|---|
| RF IC | Semtech SX1262 + discrete PA/LNA |
| Frequency Bands | 169 / 433 / 868 / 915 MHz, 1200 MHz |
| Max Output Power | +33 dBm (2W) |
| RX Sensitivity | -148 dBm (LoRa, typ.) |
| Data Rate | 0 – 62.5 kbps (LoRa) |
| TX Current @33 dBm | 1200 mA (peak – milliseconds only) |
| RX Current | 15 mA (typ.) |
| Standby Current | 12 μA |
| Interface | SPI |
| PCB | 4‑layer, impedance controlled |
| Dimensions | 36 × 24 × 3 mm |
| Operating Temp | -40°C to +80°C |
| Price | $9.90 |
The module covers all major Sub‑1GHz ISM bands and plays perfectly with LoRaWAN stacks. Use it in gateways that need to cover a whole city, or in end‑nodes that must run for years on a single battery. Applications include LoRaWAN gateways, smart meters (AMR/AMI) in basements and pits, industrial sensors (tank levels, vibration monitors, air quality) in remote locations, and asset trackers following containers, pallets, or vehicles across continents.
The N428AS is the flagship of Coral RF‘s LoRa radio module line — delivering +37 dBm (5 watts) of output power while maintaining the same -148 dBm sensitivity. With a link budget exceeding 185 dB, this module enables reliable communication over tens of kilometers in challenging non‑line‑of‑sight conditions. It is rated for -40°C to +80°C operation, ensuring reliability in remote mining sites, offshore platforms, and harsh agricultural environments.
| Parameter | N428AS |
|---|---|
| RF IC | Semtech SX1262 + high‑power PA/LNA |
| Frequency Bands | 169 / 433 / 868 / 915 MHz, 1200 MHz |
| Max Output Power | +37 dBm (5W) |
| RX Sensitivity | -148 dBm (LoRa, typ.) |
| Interface | SPI |
| Dimensions | 36 × 24 × 3 mm |
| Price | $14.90 |
The N428AS is designed for professional LoRaWAN gateways, private long‑range networks, and extreme‑range telemetry applications where maximum coverage area is the primary requirement.
| Model | Max TX Power | Equivalent | RX Sensitivity | Standby Current | Dimensions | Price |
|---|---|---|---|---|---|---|
| N401AS | +22 dBm | 158 mW | -148 dBm | 1 μA | 20×17×3 mm | $3.80 |
| N425AS | +27 dBm | 500 mW | -148 dBm | 0.2 μA | 30×21×3 mm | $5.30 |
| N426AS | +30 dBm | 1 W | -148 dBm | 0.2 μA | 36×24×3 mm | $6.00 |
| N427AS | +33 dBm | 2 W | -148 dBm | 12 μA | 36×24×3 mm | $9.90 |
| N428AS | +37 dBm | 5 W | -148 dBm | — | 36×24×3 mm | $14.90 |
A LoRa radio module alone provides the physical layer — it can send and receive chirps. But to build a scalable, secure, interoperable IoT network, you need LoRaWAN (Long Range Wide Area Network), the network protocol that sits on top of LoRa modulation, defining how devices connect, send, and receive messages through gateways to a network server. LoRa is the physical layer. LoRaWAN is the rules of the conversation.
The LoRaWAN specification defines three device classes, each balancing power consumption against downlink responsiveness:
Class A is the baseline. Every LoRaWAN device must support it, and it’s the most power‑efficient option, ideal for battery‑powered devices. A device sends an uplink whenever it needs to. Right after that, it opens two short receive windows — RX1 and RX2 — for possible downlinks from the network. If nothing comes in, it goes back to sleep until the next uplink. Downlink messages can only be delivered right after an uplink.
Pros: Lowest power use. Works well for devices that send data infrequently. Simple to deploy and scale. Cons: High downlink latency. Server can only send data after the device transmits. Not suitable for real‑time control.
Class B builds on Class A by adding scheduled receive slots. It‘s a middle ground between Class A’s efficiency and Class C‘s responsiveness. The network sends out regular time‑synced beacons. Devices use these to align their internal clocks. Alongside the two receive windows after an uplink, Class B devices also open “ping slots” at specific times. This lets the network send downlinks on schedule, reducing latency compared to Class A.
Pros: Lower downlink latency than Class A. Can do scheduled unicast or multicast messages. Still possible to run on batteries. Cons: Higher power use than Class A. Requires network and device time sync. Slightly more complex setup.
Class C keeps the receive window open almost all the time. It’s for applications where immediate action matters more than saving power. Like Class A, there are RX1 and RX2 windows, but RX2 stays open continuously, only closing during an uplink transmission. This means the server can send a downlink almost instantly at any time.
Pros: Lowest downlink latency. Real‑time control possible. Can receive data at any moment. Cons: High power consumption. Rarely practical for battery use. More sensitive to network interference.
Class A listens only right after it talks. Class B listens after it talks and also at agreed times. Class C listens almost all the time. Class A uses the least power but has the longest wait for downlink. Class B trades a bit of power for faster responses. Class C is always ready but needs constant power.
Application‑focused recommendation:
Battery‑powered remote sensors (soil moisture, water meters, wildlife trackers) → Class A
Periodic control with moderate latency (street lighting, irrigation schedules) → Class B
Mains‑powered gateways and real‑time actuators → Class C
Beyond SMD modules, Coral RF provides a comprehensive selection of USB dongles for LoRa and other Sub‑1GHz protocols, including LoRa SX1262, CC1120, CC1125, CC1312, and CC1314 dongles, as well as Zigbee and BLE dongles based on CC2538, CC2650, CC2651, CC2652 with optional CC2592 PA.
The N431AP is a plug‑and‑play USB LoRa dongle with +22 dBm output power, supporting 169/433/868/915 MHz and 1200 MHz bands. It functions as a portable spectrum sniffer, gateway adapter, and development tool, pre‑loaded with firmware that allows host control via AT commands.
The dongle can be used as a LoRaWAN gateway for small‑scale IoT deployments, collecting data from LoRa sensors (e.g., temperature, humidity, motion) and forwarding it to a server or the cloud. Its compact 37×17×7 mm enclosure with USB interface makes it ideal for wireless testing, protocol evaluation, and gateway applications. All dongles feature a compact 37×17×7 mm enclosure with USB interface, ideal for wireless testing, protocol evaluation, and gateway applications.
For professional gateways requiring extended coverage, developers can integrate the N427AS or N428AS high‑power modules into custom gateway designs, achieving 2‑5 watt output power for city‑wide or regional LoRaWAN coverage.
Coral RF offers both LoRa and GFSK (FM) modules in its portfolio. Understanding the trade‑offs between the two modulation schemes is critical for selecting the right radio for your application.
| Criterion | LoRa (SX1262) | GFSK (CC1310/CC1101) |
|---|---|---|
| RX Sensitivity | -148 dBm | -124 dBm @ 0.625 kbps |
| Data Rate (LoRa mode) | 0.018 – 37.5 kbps | 0.3 – 500 kbps |
| Latency | High (seconds at SF12) | Low (microseconds) |
| Range (LOS) | 15+ km | 5–10 km |
| Modulation | Chirp Spread Spectrum | Gaussian Frequency Shift Keying |
| Best For | Deep penetration, occasional uplinks | Real‑time control, moderate throughput |
Choose LoRa radio modules when:
You need maximum range (10–30 km in open areas)
Devices are battery‑powered and transmit infrequently (once per hour/day)
You require deep penetration through buildings, basements, or foliage
You are deploying a LoRaWAN network with standard gateways
Your data payloads are small (< 243 bytes per packet)
Choose GFSK (FM) modules when:
You need real‑time bidirectional control (latency < 10 ms)
Data rates above 100 kbps are required
You are implementing a proprietary lightweight protocol
Your deployment is short‑range (< 5 km) with line‑of‑sight
Coral RF offers both technologies, allowing engineers to select the optimal modulation for each specific use case within the same hardware ecosystem.
Water, gas, and electricity meters installed in basements, concrete pits, or remote utility closets need to transmit consumption data without cellular or wired connectivity. Coral RF LoRa modules — particularly the N425AS and N426AS — provide the deep penetration required to punch through concrete and the low power consumption (0.2 μA standby, < 15 mA RX) to operate for 5–10 years on a single battery pack.
The N427AS (+33 dBm) and N428AS (+37 dBm) modules are specifically designed for LoRaWAN gateways that need to cover entire cities, industrial campuses, or agricultural regions. A single gateway equipped with an N428AS can achieve 15–20 km radius coverage in open rural areas, dramatically reducing infrastructure costs compared to cellular or multi‑hop mesh networks. The physical layer is pure LoRa, so hooking it to The Things Network, ChirpStack, or any LoRaWAN server is plug‑and‑play.
Tank level monitoring at remote storage facilities, soil moisture sensors across large farms, vibration monitors on industrial equipment, and air quality sensors at construction sites — all benefit from LoRa‘s long range and low power. Coral RF modules operating in Class A mode wake up once per hour, transmit a small data packet, and return to deep sleep. The -148 dBm sensitivity ensures reliable reception even when the device is partially obstructed by vegetation, machinery, or terrain.
Containers crossing borders, pallets moving through warehouses, and vehicles in remote regions can all be tracked using LoRa radio modules. Unlike GPS trackers that require cellular backhaul and drain batteries quickly, LoRa asset trackers can operate for months or years on a coin cell by reporting location only when the asset moves or on a scheduled basis. Coral RF‘s compact N401AS module (20×17×3 mm) is ideal for embedding into asset tags and logistics tracking devices.
Street lights, parking sensors, waste bin monitors, and environmental sensors deployed across a city can be connected through a single LoRaWAN gateway. Class B operation allows scheduled downlinks for actuator control (dimming lights, adjusting irrigation schedules) while maintaining battery efficiency. Coral RF USB dongles (N431AP) provide an easy entry point for developers prototyping smart city applications.
LoRa technology is enabling off‑grid communication networks for backcountry safety, remote research stations, and disaster response. With a Coral RF LoRa module and a simple antenna, it is possible to establish reliable data links over 15+ kilometers without any cellular infrastructure.
The maximum range of a LoRa radio module is determined by its link budget — the difference between transmit power and receiver sensitivity, minus path loss. Coral RF‘s N428AS delivers a link budget of:
Link Budget = TX Power + RX Sensitivity
= +37 dBm - (-148 dBm) = 185 dB
In free‑space path loss (FSPL) terms, 185 dB of link budget at 868 MHz translates to:
d ≈ 47,000 meters ≈ 47 km
This theoretical free‑space range of 47 km is rarely achieved in practice due to obstacles, Fresnel zone clearance, and atmospheric conditions. However, real‑world deployments with N428AS in open rural areas consistently achieve 15–30 km reliable links, while N427AS achieves 10–15 km, and N425AS achieves 5–10 km.
For NLOS (non‑line‑of‑sight) conditions — through buildings, trees, or terrain — the effective range reduces by 50–90% depending on obstacle density. The -148 dBm sensitivity remains critical in these conditions, allowing the receiver to decode signals that are 10–20 dB below the noise floor.
LoRa modulation uses spreading factors (SF) from SF7 to SF12. Higher spreading factors increase sensitivity and range but reduce data rate and increase time‑on‑air (ToA):
| Spreading Factor | Data Rate (approx) | Sensitivity (approx) | Time‑on‑Air (100 bytes) |
|---|---|---|---|
| SF7 | 5.5 kbps | -123 dBm | ~50 ms |
| SF8 | 3.1 kbps | -126 dBm | ~100 ms |
| SF9 | 1.8 kbps | -129 dBm | ~200 ms |
| SF10 | 1.0 kbps | -132 dBm | ~400 ms |
| SF11 | 0.6 kbps | -135 dBm | ~800 ms |
| SF12 | 0.3 kbps | -148 dBm | ~1,600 ms |
Coral RF LoRa modules support all spreading factors from SF5 to SF12, allowing engineers to dynamically adjust the trade‑off between range, data rate, and battery consumption based on real‑time link conditions. The SX1262‘s excellent -148 dBm sensitivity at SF12 is the key differentiator — no other Sub‑1GHz modulation can decode signals that weak.
When a Coral RF LoRa module is deployed in a LoRaWAN network, the network server can use Adaptive Data Rate (ADR) to automatically adjust the device‘s spreading factor and transmit power based on received signal strength and link quality. Devices close to a gateway can use SF7 and lower TX power to minimize time‑on‑air and power consumption; devices at the edge of coverage can use SF12 and maximum TX power to maintain the link. This automatic optimization dramatically improves network capacity and battery life across large deployments.
All Coral RF LoRa SMD modules expose the full SX1262 pinout via SPI interface, giving developers complete control over the radio‘s configuration, sleep states, and custom protocol implementation. The N401AS module leads all pins out of SX1262 for secondary development. The module supports LoRaWAN and Arduino, and a complete SX1262 datasheet is available for download from Semtech. Coral RF provides:
SPI driver libraries for popular platforms (Arduino, STM32, ESP32, Raspberry Pi)
LoRaWAN stack examples for The Things Network and ChirpStack
AT command firmware for UART‑based modules (when paired with an onboard MCU)
Reference schematics for integrating modules into custom PCBs
For developers who prefer a higher‑level interface, Coral RF‘s USB dongles come pre‑loaded with firmware that allows host control via AT commands over USB virtual COM port, making them plug‑and‑play for PC‑based development.
When integrating a Coral RF LoRa module into a custom PCB, several factors affect RF performance:
Impedance matching: The antenna trace must be designed as a 50Ω controlled impedance line. Coral RF modules are pre‑matched for 50Ω output.
Decoupling: Place 0.1 μF and 10 μF capacitors close to the module‘s power supply pins to minimize ripple and noise.
Shielding: The module includes a shielded can, but surrounding circuitry should be isolated from the RF section.
Antenna selection: Choose an antenna resonant at the operating frequency (433/868/915 MHz). A high‑gain external antenna (e.g., 5–8 dBi Yagi) can dramatically extend range for gateway applications.
Thermal management: The N427AS and N428AS modules draw significant peak current (up to 1200 mA) during transmission, requiring adequate power supply decoupling and PCB copper pour for heat dissipation.
Coral RF‘s LoRa radio module portfolio — built on Semtech’s SX1262 — provides a complete solution for any long‑range IoT application:
N401AS (+22 dBm, $3.80): Low‑cost entry point. Ideal for prototyping, battery‑powered sensors, and low‑density networks where maximum range is not critical.
N425AS (+27 dBm, $5.30): Cost‑optimized high power. Perfect for smart meters, industrial sensors, and asset tracking requiring 5–10 km range at moderate cost.
N426AS (+30 dBm, $6.00): 1‑watt LoRaWAN‑ready module. Suitable for medium‑range industrial sensors and private LoRa networks.
N427AS (+33 dBm, $9.90): 2‑watt professional module. Designed for LoRaWAN gateways, AMI smart metering, and applications requiring 10–15 km coverage.
N428AS (+37 dBm, $14.90): 5‑watt extreme‑range flagship. Built for professional LoRaWAN gateways, private long‑range networks, and mission‑critical telemetry requiring maximum coverage area.
All modules support global Sub‑1GHz ISM bands (169/433/868/915 MHz and 1200 MHz), share the same SPI interface for easy migration across power levels, and are available with USB dongle development tools for rapid prototyping. Whether you are deploying a LoRaWAN network across a smart city, monitoring remote agricultural assets, tracking containers across supply chains, or building an off‑grid communication system, Coral RF provides the LoRa radio modules to get your IoT project off the ground — and keep it connected for years to come.