tl;dr
A tracker device which sends GPRS telemetry has EMI issues. The original design had the antenna connected straight to the "ANT" pin of the GPRS chip. When a "0R" resistor on the feedline path was replaced with a 1pF capacitor, the EMI issues disappeared, and I'm wondering why - is a DC-blocking capacitor actually required?
Background
I've "inherited" a GPS-tracker GPRS-telemetry type of device, which I wrote some extra software for.
The device collects data from an accelerometer, magnetometer, GPS, and records audio. Data is stored on a SD card. Also, twice per minute, an aggregated packet of telemetry is sent over the GPRS link to a server in a fire-and-forget style (UDP).
The hardware design of the device is not stellar, but looks good enough. The GPRS chip (ublox Sara G350) is mounted on a separate 2-layer PCB with a lot of ground plane on both sides, heavily stitched. The GPRS antenna feedline is short and is a coplanar waveguide with ground, correctly dimensioned for 50Ω impedance. There's more than enough bypass capacitance on the GPRS chip VCC, my only gripe is that the small nF/pF caps could have been closer to the VCC pins.
"hiccups"
During testing it was discovered that the device has a latent EMI problem, which was causing instability and corrupted data: when operated in an area with poor network coverage, on each 30-second interval (i.e. coinciding with the GPRS transmit), one can see the following effects:
- battery voltage dips slightly (which is expected and not EMI-related - just a result of the GPRS chip pulling a lot of power);
- input power voltage measurement sees phantom voltage spikes of a few millivolts;
- accelerometer samples contain garbage for a few 10s of ms;
- the audio chip locks up and requires a reinit (rarely);
- the main MCU resets without a reason (very rare)
I'm calling these tell-tale signs "hiccups", because they occur spuriously, and everything is otherwise fine in between them.
The core EMI issue might be something related to the I²C bus, as sensors not on the I²C like the GPS seem unaffected. But I'll ask another question for it after I understand it more, as it would be too broad right now.
The devices do not hiccup in my office, but if I take the device and drive it on a mountain road, where the network reception is known to be bad, you can later review the stored telemetry in the SD card and see how the hiccups appear and increase in intensity as the signal gets worse and worse. The GPRS chip also reports RSSI. The hiccups and RSSI are well correlated.
Matching circuit
The device can use either an internal GPRS antenna (PCB-type), or an external antenna on a SMA connector. There are footprints for a π filter between the GPRS chip and the antenna. After the filter, there's also a footprint for a U.FL connector, used for the external antenna configuration:
- internal config: matching circuit passives are populated, U.FL connector is not populated, the antenna (Antenova A10340H) is soldered as per datasheet requirements;
- external config: matching circuit is just a 0R; feedline is cut from the U.FL onwards; the U.FL connector is populated, a short coaxial cable leads to the SMA connector outside the enclosure. The Molex 2144290001 antenna is used.
I initially looked into the "internal antenna" devices, and noticed that the matching circuit was different from what Antenova recommended. We changed it to match their reference circuit, and the hiccups practically disappeared.
The "external antenna" devices were less hiccupy from the start, but still had issues, and the following sentence from the Antenova datasheet caught my eye (emphasis mine):
I pored through the GPRS chip datasheet to see if they too recommend a DC blocking cap, but found nothing. Nevertheless, I decided to test and replaced the 0R series 0603 resistor of the π circuit to a 1pF 0603 C0G capacitor. What I saw was:
- the hiccups virtually disappeared;
- the reported GPRS RSSI was lower by some 5-10%;
- packet loss between the device and the server was comparable (since it is UDP, if there's no network coverage, the data is lost).
The comparison between the two configurations (0R vs 1pF) uses the same device, mounted on the same car, the same antenna orientation, diven along the same route through a mountain road with known bad reception in certain areas. The only difference should be the series element of the π filter. I've also replicated these results using another device with external antenna, which again went through the 0R→1pF replacement.
Questions
- is a DC-blocking capacitor really required, as the documentation (Molex antenna datasheet and the u-blox Sara G3xx system integrator's manual) mentions nothing in that regard?
- what could be the reason that adding the capacitor reduced the EMI issue?