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Monthly Image: Great Blue Heron

This Great Blue Heron caught a bright orange goldfish in the Vassar Farm Pond just before I rode past, spotted the scene, and fumbled my camera out of the underseat bag.

The heron hurked the fish down, with the abrupt right-angle bend in its neck marking the fish’s current location:

Great Blue Heron - swallowing

Great Blue Heron – swallowing

A bit of wiggling & jiggling put the meal in the right place and the bird relaxed:

Great Blue Heron - ruminating

Great Blue Heron – ruminating

A postprandial flight around the pond apparently settled the fish:

Great Blue Heron - takeoff

Great Blue Heron – takeoff

It landed on a snag a few dozen feet from where it started, then proceeded to look regal:

Great Blue Heron - idling

Great Blue Heron – idling

Those things really do look like pterodactyls in flight!

 

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LF Crystal Tester: First Light!

After adding a MAX4165 buffer amp to drive the crystal test fixture at 1 µW and a MAX4255 to amplify the 1 mV crystal output by 40 dB, then removing the AD8310 log amp module’s 50 Ω terminator to better match the MAX4255’s output drive ability, this happened:

Log V vs F - 32766 4 Hz - CX overlay

Log V vs F – 32766 4 Hz – CX overlay

That’s:

  • A 32.768 kHz quartz resonator
  • A ±2 Hz span centered on 32.766 kHz
  • 0.10 Hz frequency steps
  • The 22 pF cap out / in circuit (left & right peaks, respectively)
  • Log amp output at 24 mV/dBV, with a nominal -108 dBV intercept at 0 V

With a 4 Hz span and 0.1 Hz steps, you get only 41 samples along the X axis: it’s supposed to look spotty.

The 2.2 V response at the top of the left peak corresponds to 2.2 / 24 mV/dBV = 91.7 dBV, then you knock off the -108 dBV intercept to get -16.3 dBV. The valley at 1.88 V is 78.3 – 108 = -29.7 dBV, down about 13 dBV from the corresponding peak. The peak-to-baseline over on the right looks like 200 mV = 8 dBV.

The AD8310 datasheet uses “intercept” in a manner I had not previously encountered. They plot the AD8310 output in volts against the input signal level in dBV, with the “intercept” marking the extrapolated point where the straight line with slope 24 mV/dBV crosses the X axis: the equation is volts = slope*(input dBV – intercept dBV). Back in the day, I learned the intercept was where the line crossed the Y axis at X=0, so the straight-line equation was simply y = slope*x + intercept. Took me a while to figure that out.

Then subtract the 40 dB gain from the crystal output to the log amp to get -56 dbV = 1.6 mV. That’s close enough to the 1 mV before adding the MAX4255. All those numbers seem slightly squishy, but they’re close enough.

The peaks are 13-ish spots apart, which corresponds to 1.3 Hz, which is roughly the 1 Hz I measured with the HP8591 spectrum analyzer, The baseline is down 8 dBV, not quite as much as the analyzer’s 13 dB at 1 Hz offset from the peaks.

What’s not right: the parallel-resonant dip to the right of each peak should be at the same frequency for both traces, because it doesn’t vary with added series capacitance, but it’s pretty much tracking the series-resonant peak frequency.

The amount of noise on the log amp output looks like 50 mV = 2 dBV. That’s a lot, compared to the 13 dBV response, but some judicious averaging may save the day.

The 22 MHz GBW of the MAX4255 rolls off the high end at 220 kHz. I AC coupled the signal chain with 10 µF dipped tantalum caps from my lifetime supply, which may pass entirely too much of the low end; the settling time is way too long. This probably requires smaller caps and maybe an actual bandpass filter.

The 50 mV-ish noise on the DAC output driving the X axis suggests my proto board layout isn’t up to the demands of this circuit: there shouldn’t be any noise in that direction.

Some poking around suggests the OLED display is way noisier than you’d (well, I’d) expect. The faded-out lower section in the picture below suggests it’s refreshing one line = 128 pixels at a time. More study is indicated.

But, if you squint hard enough, this lashup produces numbers in the right ballpark. Given that it’s a collection of cheap-as-dirt eBay modules flying in formation, that’s nothing to sniff at:

Crystal Tester - First Light

Crystal Tester – First Light

Those “gold tone” SMA connectors really make it look like serious RF hardware, don’t they? [grin]

The round twiddlepot floating on the white pillow trims the DDS output voltage by a factor of two = 6 dB. Combined with the 0-6-12-18 dB gain steps provided by the header in front of the MAX4165 (to the right of the pillow), you can set the drive voltage so the crystal gets (roughly) its rated 1 µW maximum drive power.

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Proto Board Holder: Revised Screw Mounts

Improving the crystal tester’s (nonexistent) grounding requires a band of copper tape around the inside of the proto board holder. Rather than cut the tape lengthwise to fit the holder, a new one will be just tall enough:

Proto Board - 80x120 - revised inserts - Slic3r

Proto Board – 80×120 – revised inserts – Slic3r

While I was at it, I deleted the washer recesses, because those didn’t work out well, and fiddled the screw holes to put the inserts in from the bottom:

Proto Board - 80x120 - revised inserts - detail - Slic3r

Proto Board – 80×120 – revised inserts – detail – Slic3r

Although the overhang inside the holes will be ugly, I’ll epoxy the inserts flush with the bottom and nobody will ever know.

The copper tape now makes a tidy ground strap:

Crystal Tester - ground strap - rear

Crystal Tester – ground strap – rear

With a gap in the front to eliminate the obvious loop:

Crystal Tester - ground strap - front gap

Crystal Tester – ground strap – front gap

The OpenSCAD source code as a GitHub Gist:

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Generic I²C 128×64 OLED Displays: Beware Swapped VCC and GND

A batch of 1.3 inch white I²C OLED displays arrived from halfway around the planet, so I figured I could run a quick acceptance test by popping them into the socket on the crystal tester proto board:

White 1.3 inch OLED on crystal tester

White 1.3 inch OLED on crystal tester

The first one flat-out didn’t work, as in not at all. The original display continued to work fine, so I compared the old & new displays:

OLED Modules - pinout difference

OLED Modules – pinout difference

Yup, swapped VCC and GND pins. I should be used to that by now.

I rewired the socket, tried the new displays, undid the change, popped the original display in place, and all is right with the world. Somewhat to my surprise, all five new displays worked, including the one I’d insulted with reversed power.

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Goslings at Vassar Farm Pond

I watched the Canada Goose family paddling around the pond:

Goslings at Vassar Farm Pond - 2017-06-04 - family

Goslings at Vassar Farm Pond – 2017-06-04 – family

A hiker on the trail around the pond brought them to DEFCON 4:

Goslings at Vassar Farm Pond - 2017-06-04 - alert

Goslings at Vassar Farm Pond – 2017-06-04 – alert

The little ones aren’t triphibans yet, but they know the drill:

Goslings at Vassar Farm Pond - 2017-06-04 - wing exercise

Goslings at Vassar Farm Pond – 2017-06-04 – wing exercise

Maybe he only does that when Mom’s not watching?

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Under-cabinet LED Strip IR Sensor: Re-aimed

The under-cabinet LED strips work wonderfully well, except that the IR sensor seemed rather hypersensitive, so I added a small reflector made of shiny steel:

Under-cabinet light - IR sensor mirror

Under-cabinet light – IR sensor mirror

Even though I rounded those corners and deburred the edges, it does look a bit threatening, doesn’t it?

It moves the sensor’s hotspot back about half a foot, which seems Good Enough to eliminate false triggering from normal activity over the cutting board.

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Teledyne 732TN-5 Relay: Zowie!

The first pass at the crystal tester used a manual jumper to switch the 33 pF series capacitor in / out of the circuit:

Quartz crystal resonance test fixture

Quartz crystal resonance test fixture

With an Arduino close at hand, however, a relay makes somewhat more sense. For long-forgotten reasons, I have a small fortune in Teledyne 732TN-5 relays intended for RF switching:

Teledyne 732TN-5 Relay

Teledyne 732TN-5 Relay

The 7820 date code on the side suggests they’ve been in the heap basically forever, although some fractions of Teledyne still exist and you can apparently buy the same relay today at 50 bucks a pop. It’s definitely overqualified for this job and you can surely get away with an ordinary DIP DPDT (or, heck, even SPST) relay.

It seems I picked a hyper-bright white LED: the red ink tones it down a bit. Black might be more effective. A diffused LED may be in order.

The “TN” suffix indicates a built-in transistor driver with a catch diode on the relay coil, so the relay needs power, ground, and a current drive into the transistor’s base terminal:

Teledyne 732TN relay - drive schematic

Teledyne 732TN relay – drive schematic

Even with the internal catch diode, I ran the +5 V power through a 12 Ω resistor to a 10 µF cap in hopes of isolating the inevitable switching transients from the DDS and log amp. As a result, the turn-on transient isn’t much of a transient at all:

Teledyne 732TN Relay - turn-on transient

Teledyne 732TN Relay – turn-on transient

The 560 mV drop suggests a 47 mA coil current through the 12 Ω resistor, just about spot on for a 100 Ω coil.

The energy stored in the coil makes the turn-off transient much steeper:

Teledyne 732TN Relay - turn-off transient

Teledyne 732TN Relay – turn-off transient

Note the 1.5 µs delay from the falling control input to the relay opening. Granted, it’s running at 4.7 V, not the rated 5 V, but that’s still rather peppy. The turn-on delay seems to be about the same, making the datasheet’s “6 ms nominal” operating time look rather conservative.

Dang, that’s a nice gadget!

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