Phil Karn KA9Q, Randy Standke KQ6RS and students at the Mount Carmel High School Amateur Radio Club have constructed and deployed an amateur radio marine buoy, callsign KQ6RS, transmitting 14.0956 MHz USB WSPR

Over the past year, Randy, KQ6RS and I have mentored the MCHSARC in designing and constructing a simple marine buoy that was deployed from the R/V Sally Ride this morning about 700 km off the coast of southern California. It is up and transmitting WSPR on 20m using the callsign KQ6RS, and is being received all over the US and into Canada and Brazil.

The electronics is the 20m WSPR version of the WB8ELK "pico tracker" that has been flown quite a few times (including by us) on long-duration balloons. We removed the solar panels and substituted 21 ordinary alkaline D-cells wired to supply 4.5V. We estimate the battery lifetime will be 6 months.

The basic design was inspired by Bob, WB4APR, at the US Naval Academy. Physically, the buoy is just a 5' section of 4" PVC pipe, ballasted at one end to float vertically in the water. The top is closed by a sewer pressure test plug I found at Home Depot; it has a bolt in the centre that acts as a convenient feed-through and mounting point for the antenna, a stainless steel CB whip with a matching network designed, tested and carefully tuned by Randy. We use the sea as a counterpoise, but to avoid direct metal/seawater contact we lined the inside of the pipe with copper tape to form a capacitive connection. We probably spent too much time on this; Randy even modelled the electrical fields in the seawater with a professional RF analysis package.

In our first flotation tests in Randy's swimming pool, we found that the ballasted pipe, by itself, was remarkably stable in pitch, roll, sway and surge but oscillated a lot in heave (up and down). To damp this Randy added cross arms at the water line to add drag in the vertical direction.

(It wasn't our intent to mimic a religious icon but that's where the physics went.) Tuning the antenna required seawater, so Randy did it from a dock on Mission Bay here in San Diego.

We tried to make this thing as rugged as we could. (My favourite saying to the students was that the sea “always” wins in the end, but we can delay that long enough to be useful.) Everything inside is held in place with epoxy or polyurethane foam. Randy reinforced the sewer plug with a PVC end cap with a hole cut in the centre. Although the antenna is stainless steel, Randy covered it with a type of heat shrink with a waterproofing compound inside. Activation was by removing an external magnet placed over a parallel pair of normally closed magnetic reed switches. (Using two instead of one was my idea.) We even argued how to guard against the crew forgetting to remove the magnet before deployment. Randy found some adhesive that would dissolve and let the magnet fall away; I suggested a big REMOVE BEFORE FLIGHT tag and a float that would pull it away if it was tossed into the water.

That left the problem of deployment. We couldn't just drop it close to the coast because it would quickly wash back up on the beach. We needed a boat ride. We were originally going on an NOAA vessel in April, but that trip was cancelled due to the pandemic. Randy secured a trip on the R/V Sally Ride, a research ship operated by Scripps Institute of Oceanography and homeported here in San Diego.

This map shows the "lawnmowing" pattern they follow to measure and sample seawater off southern California. We were deployed early on the morning of July 16 at the most southwestern point shown here - https://calcofi.org/cruises/2020-cruises/calcofi-2007sr.html

The first report was at 12:52:30 UTC, July 16, from 29 51.25N, 123 37.50W. That's grid square CL89eu, which I figure is pretty rare for grid hunters. The current carried us east into CL89fu at 20:32:30. This is a little surprising since we thought the currents in that area are to the southwest. But that's why you do science!

Track on aprs.fi 0- https://aprs.fi/#!call=a%2FKQ6RS-1&others=1&timerange=604800&tail=3600

wsprnet.org - http://wsprnet.org/drupal/wsprnet/map