In Sub-1GHz wireless systems, the power amplifier (PA) is a critical component that determines communication distance and link reliability. TI's CC1190, as a front-end IC integrating a PA and LNA, is commonly paired with transceivers such as the CC1310, CC1312, and CC1125, boosting output power to over +27dBm while improving receiver sensitivity. However, the success of PA design depends not only on the accuracy of the schematic but also on a comprehensive consideration of RF matching, PCB layout, and operational practices.
This article combines typical application scenarios for the CC1190, summarizing a practical PA design guide covering matching network tuning, hot-swapping risk mitigation, ESD protection, and more.
In Sub-1GHz applications such as Wi-SUN and industrial sensing, wireless transmission distance is primarily limited by two factors: transmit power and receiver sensitivity.
The CC1190's PA amplifies the transceiver's output (typically +3 to +10dBm) to +27dBm. Every 6dB increase approximately doubles the distance.
The internal LNA reduces the noise figure of the receive path by approximately 5dB, allowing the gateway to "hear" weaker signals.
Therefore, the CC1190 is a popular choice for building long-range, high-reliability gateways and commissioning tools.
The output impedance of the CC1190 is not standard 50Ω and must be converted to 50Ω at the antenna side through a matching network. Poor matching can lead to:
Power loss: Significant energy is reflected back to the PA, resulting in actual radiated power far below the rated value
Spurious emissions exceedance: Harmonics increase abnormally, preventing FCC/CE certification
Reduced PA efficiency: Reflected power is converted to heat, increasing thermal stress on the chip
TI provides reference designs for the CC1190 for various frequency bands such as 868MHz and 915MHz (including schematics, BOM, and PCB layout).
Copying the PCB layout of the reference design is more important than copying the schematic—the parasitic parameters of RF traces have a significant impact on matching.
Even when strictly following the reference design, a new PCB layout may still require fine-tuning. It is recommended to reserve a π-type matching network at the RF output and use a network analyzer for tuning.
Tuning Targets:
S22 (output reflection coefficient) < -10dB
Second harmonic meets regulatory requirements (e.g., < -30dBm in Europe)
Tuning Process:
Use a network analyzer to measure the impedance at the antenna port
Fine-tune the inductors and capacitors in the π-network until the impedance on the Smith chart converges to 50Ω
Use a spectrum analyzer to check harmonics, adding a notch filter if necessary
TI has officially confirmed that the CC1190 does not require additional VSWR protection circuits (such as circulators or isolators). However, this does not mean it can withstand "hot-swapping" operations.
| Operation Scenario | Risk Level | Reason |
|---|---|---|
| Connecting/disconnecting antenna when device is idle | Very low | No PA output, no stress |
| Disconnecting cable while device is actively transmitting | Relatively high | ① Instantaneous total reflection, creating high VSWR ② Possible micro-arcing at the connector during disconnection, impacting the PA output stage |
Conclusion: Developing the habit of "stop transmission first, then connect/disconnect" is the most effective way to protect the PA.
The RF pins of the CC1190 have an ESD rating of HBM 1500V. In dry environments, a single accidental electrostatic discharge can cause permanent damage.
Operational Guidelines:
Before connecting or disconnecting RF cables, first touch a grounded metal surface to discharge static electricity from your body
Use an ESD mat on the workbench and wear an anti-static wrist strap
Avoid frequent plugging/unplugging in low-humidity environments
The absolute maximum input RF level for the CC1190 is +10dBm. If the front-end CC1310's output power is set too high, or under abnormal conditions where reflected power adds, the input signal may exceed this limit, causing internal damage to the PA.
Recommendations:
Strictly control the output power of the CC1310 to stay within the CC1190's input range (typically < +8dBm)
During debugging, use a spectrum analyzer to verify the signal amplitude at the PA input
High-power PAs generate significant heat during operation. Good thermal design is essential for long-term reliability.
Add thermal vias: Place 4 to 9 vias under the CC1190 PowerPAD, connecting to the ground plane, to help conduct heat away
Maintain a continuous ground plane: Ensure the ground plane in the PA area is uninterrupted to avoid additional losses due to ground loops
Keep heat-sensitive components away: Maintain distance between the PA and sensitive components such as crystals
| Check Item | Status |
|---|---|
| Follow TI reference design PCB layout | ☐ |
| Reserve π-type matching network at RF output | ☐ |
| Use network analyzer to tune S22 < -10dB | ☐ |
| Use spectrum analyzer to verify second harmonic meets regulations | ☐ |
| Confirm CC1310 output power < +8dBm | ☐ |
| Add thermal vias under PowerPAD | ☐ |
| Establish "stop transmission before connecting/disconnecting" practice | ☐ |
| Implement ESD protection measures at the workbench | ☐ |
The CC1190 is a mature and robust RF front-end IC. Its design is not overly complex, but it demands attention to detail. Successful PA design = precise matching network + strict PCB layout + standardized operational practices.
By following TI reference designs, reserving matching networks, avoiding hot-swapping, and strengthening ESD protection, you can fully realize the performance potential of the CC1190 and build long-range, highly reliable wireless products.
If you are developing a gateway or commissioning tool based on the CC1190, I hope this guide helps you avoid common pitfalls. If you need specific matching network parameters or PCB layout recommendations, feel free to reach out for further discussion.