Archive for category Amateur Radio
LF Crystal Tester: DDS Buffer Amp
Posted by Ed in Amateur Radio, Electronics Workbench on 2017-06-20
The Big Ideas: the DDS output, being more-or-less constant, needs a variable-gain amp to set the crystal drive level. The amp also fixes the impedance mismatch between the DDS output and the crystal, which may not be much of a problem for the (very) high ESR quartz tuning fork resonators in play.
The AD8950 DDS output feeds a 70 MHz (-ish) elliptical reconstruction filter chopping off image frequencies descending from the 125 MHz sampling clock, with a 100 Ω (-ish) output impedance that’s just about purely resistive at 60 kHz. An on-board 3.9 kΩ resistor (labeled with 392 on their schematic) sets the full-scale output current to 10 mA for a peak voltage of 1 V. The module uses only the + output of the differential pair, which means the sine wave runs from 0 V to 1 V: 1 Vpp = 500 mVpeak = 353 mVrms (ignoring the 500 mV offset).
Pin header J3 normally sports a jumper to connect the 3.9 kΩ RSET resistor, but you can insert an external resistor to increase the resistance and decrease the output current:
IOUT = 32 × 1.248 V / RSET
A little hot-melt glue action produced a suitable lashup from a 5 kΩ trimpot:
AD9850 DDS Module – 5 k external RSET trimpot
The pillars of green wire insulation forestall screwdriver shorts to the bare pin headers, although that’s less of risk with the upper insulating foam sheet in place:
Crystal Tester – First Light
A 5 kΩ trimpot can vary the output voltage downward by a factor of 2 = -6 dB, more or less.
All the quartz tuning fork resonator specs I’ve found, none of which may apply to the units on hand, seem to require no more than 1 µW drive. Given a resonator’s equivalent series resistance of around 20 kΩ (for real!), the drive voltage will be 150 mV (-ish):
1 µW = V² / 20 kΩ, so V = sqrt(20×10³) = 141 mV
The nominal version of the crystal tester had a 50 Ω input impedance, so I picked a MAX4165 op amp with mojo sufficient for anything over 25 Ω; in retrospect, a lighter load than 48 Ω would be fine.
In any event, the amp looks like this:
MAX4165 Buffer Amp
What looks like a DIP switch is really the 3×2 jumper header just to the right of the foam insulation, in front of the SOT23 space transformer PCB carrying the MAX4165. No jumper = 0 dB gain, then 6 dB steps upward from there. The -6 dB trimpot range gives more-or-less continuous output tweakage across 24 dB, -6 dB to +18 dB, which is certainly excessive. The 24 Ω terminating resistors provide 6 dB loss into the crystal, so the effective range is -12 to +12 dB, with 0 dB = 350 mVrms and -6 dB = 150 mVrms (-ish) at the crystal.
It’s a non-inverting amplifier, which (also in retrospect) probably isn’t a win:
- Yet Another Bypass Cap on the cold end of the gain-setting resistors
- Overly elaborate VCC/2 biasing to maintain sufficiently high input impedance
I’m reasonably sure all those big caps contribute to some low-level motorboating, but haven’t tracked it down.
Teledyne 732TN-5 Relay: Zowie!
Posted by Ed in Amateur Radio, Electronics Workbench on 2017-06-09
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
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
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
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
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
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!
AD9850 DDS Module: 1.3 inch I²C OLED FTW
Posted by Ed in Amateur Radio, Electronics Workbench on 2017-06-06
A white 1.3 inch I²C OLED turns out to be much more readable than the yellow-blue 0.96 inch version:
Arduino with OLED – white 1.3 inch
Of course, after you make it readable, you immediately make room to cram more data on it:
White 1.3 inch OLED on crystal tester
That’s on the proto board with the Arduino and AD9850 DDS ticking away on the left; the bright red MCP4725 DAC will eventually drive the scope’s X axis. Shifting the display to the I²C interface and cleaning up my SPI initialization code worked wonders: the DDS now steps a sine wave at 0.1 Hz (pretty nearly) intervals from 57.0 to 60.3 Hz.
AD9850 DDS Module: OLED Display
Posted by Ed in Amateur Radio, Electronics Workbench, Software on 2017-06-03
Those little OLED displays might just work:
Arduino with OLED – simulated DDS
The U8X8 driver produces those double-size bitmap characters; the default 8×8 matrix seem pretty much unreadable on a 0.96 inch OLED at any practical distance from a benchtop instrument. They might be workable on a 1.3 inch white OLED, minus the attractive yellow highlight for the frequency in the top line.
The OLED uses an SPI interface, although the U8X8 library clobbers my (simpleminded) SPI configuration for the AD9850 DDS and I’ve dummied out the DDS outputs. A soon-to-arrive I²C OLED should resolve that problem; changing the interface from SPI to I²C involves changing the single line of code constructing the driver object, so It Should Just Work.
The U8X8 driver writes directly to the display, thus eliminating the need for a backing buffer in the Arduino’s painfully limited RAM. I think the library hauls in all possible fonts to support font selection at runtime, even though I need at most two fonts, so it may be worthwhile to hack the unneeded ones from the library (or figure out if I misunderstand the situation and the Flash image includes only the fonts actually used). Each font occupies anywhere from 200 to 2000 bytes, which I’d rather have available for program code. Chopping out unused functions would certainly be less useful.
The display formatting is a crude hack just to see what the numbers look like:
int ln = 0;
u8x8.draw2x2String(0,ln,Buffer);
ln += 2;
TestFreq.fx_64 = ScanTo.fx_64 - ScanFrom.fx_64;
PrintFixedPtRounded(Buffer,TestFreq,1);
u8x8.draw2x2String(0,ln,"W ");
u8x8.draw2x2String(2*(8-strlen(Buffer)),ln,Buffer);
ln += 2;
PrintFixedPtRounded(Buffer,ScanStep,3);
u8x8.draw2x2String(0,ln,"S ");
u8x8.draw2x2String(2*(8-strlen(Buffer)),ln,Buffer);
ln += 2;
TestFreq.fx_32.high = SCAN_SETTLE; // milliseconds
TestFreq.fx_32.low = 0;
TestFreq.fx_64 /= KILO; // to seconds
PrintFixedPtRounded(Buffer,TestFreq,3);
u8x8.draw2x2String(0,ln,"T ");
u8x8.draw2x2String(2*(8-strlen(Buffer)),ln,Buffer);
ln += 2;
Updating the display produces a noticeable and annoying flicker, which isn’t too surprising, so each value should have an “update me” flag to avoid gratuitous writes. Abstracting the display formatting into a table-driven routine might be appropriate, when I need more than one layout, but sheesh.
I calculate the actual frequency from the 32 bit integer delta phase word written to the DDS, rather than use the achingly precise fixed point value, so a tidy 0.100 Hz frequency step doesn’t produce neat results. Instead, the displayed value will be within ±0.0291 Hz (the frequency resolution) of the desired frequency, which probably makes more sense for the very narrow bandwidths involved in a quartz crystal test gadget.
Computing the frequency step size makes heavy use of 64 bit integers:
// ScanStep.fx_64 = One.fx_64 / 4; // 0.25 Hz = 8 or 9 tuning register steps ScanStep.fx_64 = One.fx_64 / 10; // 0.1 Hz = 3 or 4 tuning register steps // ScanStep.fx_64 = One.fx_64 / 20; // 0.05 Hz = 2 or 3 tuning register steps // ScanStep = HzPerCt; // smallest possible frequency step
The fixed point numbers resulting from those divisions will be accurate to nine decimal places; good enough for what I need.
The sensible way of handling discrete scan width / step size / settling time options is through menus showing the allowed choices, with joystick / joyswitch navigation & selection, rather than keyboard entry. An analog joystick has the distinct advantage of using two analog inputs, not four digital pins, although the U8X8 driver includes a switch-driven menu handler.
There’s a definite need to log all the values through the serial output for data collection without hand transcription.
The Arduino source code as a GitHub Gist:
AD9850 DDS Module: Temperature Sensitivity
Posted by Ed in Amateur Radio, Electronics Workbench, Science on 2017-05-31
While tinkering with the SPI code for the AD9850 DDS module, I wrote down the ambient temperature and the frequency tweak required to zero-beat the 10 MHz output with the GPS-locked oscillator. A quick-n-dirty plot summarizing two days of randomly timed observations ensued:
AD9850 DDS Module – Frequency vs Temperature
The frequency offset comes from the tweak required to zero-beat the output by adjusting the initial oscillator error: a positive tweak produces a smaller count-per-hertz coefficient and reduces the output frequency. As a result, the thermal coefficient sign is backwards, because increasing temperature raises the oscillator frequency and reduces the necessary tweak. I think so, anyway; you know how these things can go wrong. More automation and reliable data would be a nice touch.
Foam sheets formed a block around the DDS module, isolating it from stray air currents and reducing the clock oscillator’s sensitivity:
AD9850 DDS module – foam insulation
I used the ambient temperature, because the thermocouple inside the foam (not shown in the picture) really wasn’t making good contact with the board, the readings didn’t make consistent sense, and, given a (nearly) constant power dissipation, the (average) oscillator temperature inside the foam should track ambient temperature with a constant offset. I think so, anyway.
The coefficient works out to 0.02 ppm/°C. Of course, the initial frequency offset is something like -400 Hz = 3 ppm, so we’re not dealing with lab-grade instrumentation here.
AD9850 DDS Module: Hardware Assisted SPI and Fixed-point Frequency Stepping
Posted by Ed in Amateur Radio, Software on 2017-05-30
Having conjured fixed-point arithmetic into working, the next step is to squirt data to the AD9850 DDS chip. Given that using the Arduino’s hardware-assisted SPI doesn’t require much in the way of software, the wiring looks like this:
Nano to DDS schematic
Not much to it, is there? For reference, it looks a lot like you’d expect:
AD9850 DDS Module – swapped GND D7 pins
There’s no point in building an asynchronous interface with SPI interrupts and callbacks and all that rot, because squirting one byte at 1 Mb/s (a reasonable speed for hand wiring; the AD9850 can accept bits at 140+ MHz) doesn’t take all that long and it’s easier to have the low-level code stall until the hardware finishes:
#define PIN_HEARTBEAT 9 // added LED
#define PIN_RESET_DDS 7 // Reset DDS module
#define PIN_LATCH_DDS 8 // Latch serial data into DDS
#define PIN_SCK 13 // SPI clock (also Arduino LED!)
#define PIN_MISO 12 // SPI data input
#define PIN_MOSI 11 // SPI data output
#define PIN_SS 10 // SPI slave select - MUST BE OUTPUT = HIGH
void EnableSPI(void) {
digitalWrite(PIN_SS,HIGH); // set SPI into Master mode
SPCR |= 1 << SPE;
}
void DisableSPI(void) {
SPCR &= ~(1 << SPE);
}
void WaitSPIF(void) {
while (! (SPSR & (1 << SPIF))) {
TogglePin(PIN_HEARTBEAT);
TogglePin(PIN_HEARTBEAT);
continue;
}
}
byte SendRecSPI(byte Dbyte) { // send one byte, get another in exchange
SPDR = Dbyte;
WaitSPIF();
return SPDR; // SPIF will be cleared
}
With that in hand, turning on the SPI hardware and waking up the AD9850 looks like this:
void EnableDDS(void) {
digitalWrite(PIN_LATCH_DDS,LOW); // ensure proper startup
digitalWrite(PIN_RESET_DDS,HIGH); // minimum reset pulse 40 ns, not a problem
digitalWrite(PIN_RESET_DDS,LOW);
delayMicroseconds(1); // max latency 100 ns, not a problem
DisableSPI(); // allow manual control of outputs
digitalWrite(PIN_SCK,LOW); // ensure clean SCK pulse
PulsePin(PIN_SCK); // ... to latch hardwired config bits
PulsePin(PIN_LATCH_DDS); // load hardwired config bits = begin serial mode
EnableSPI(); // turn on hardware SPI controls
SendRecSPI(0x00); // shift in serial config bits
PulsePin(PIN_LATCH_DDS); // load serial config bits
}
Given 32 bits of delta phase data and knowing the DDS output phase angle is always zero, you just drop five bytes into a hole in the floor labeled “SPI” and away they go:
void WriteDDS(uint32_t DeltaPhase) {
SendRecSPI((byte)DeltaPhase); // low-order byte first
SendRecSPI((byte)(DeltaPhase >> 8));
SendRecSPI((byte)(DeltaPhase >> 16));
SendRecSPI((byte)(DeltaPhase >> 24));
SendRecSPI(0x00); // 5 MSBs = phase = 0, 3 LSBs must be zero
PulsePin(PIN_LATCH_DDS); // write data to DDS
}
In order to have something to watch, the loop() increments the output frequency in steps of 0.1 Hz between 10.0 MHz ± 3 Hz, as set by the obvious global variables:
PrintFixedPtRounded(Buffer,ScanFreq,1);
TestCount.fx_64 = MultiplyFixedPt(ScanFreq,CtPerHz);
printf("%12s -> %9ld\n",Buffer,TestCount.fx_32.high);
WriteDDS(TestCount.fx_32.high);
ScanFreq.fx_64 += ScanStep.fx_64;
if (ScanFreq.fx_64 > (ScanTo.fx_64 + ScanStep.fx_64 / 2)) {
ScanFreq = ScanFrom;
Serial.println("Scan restart");
}
Which produces output like this:
DDS SPI exercise Ed Nisley - KE4ZNU - May 2017 Inputs: 124999656 = 125000000-344 Osc freq: 124999656.000000000 Hz/Ct: 0.029103750 Ct/Hz: 34.359832926 0.1 Hz Ct: 3.435983287 Test frequency: 10000000.0000 Delta phase: 343598329 Scan limits from: 9999997.0 at: 10000000.0 to: 10000003.0 Sleeping for a while ... Startup done! Begin scanning 10000000.0 -> 343598329 10000000.1 -> 343598332 10000000.2 -> 343598336 10000000.3 -> 343598339 10000000.4 -> 343598343 10000000.5 -> 343598346 10000000.6 -> 343598349 10000000.7 -> 343598353 10000000.8 -> 343598356 10000000.9 -> 343598360 10000001.0 -> 343598363 10000001.1 -> 343598367 10000001.2 -> 343598370 10000001.3 -> 343598373 <<< snippage >>>
The real excitement happens while watching the DDS output crawl across the scope screen in relation to the 10 MHz signal from the Z8301 GPS-locked reference:
DDS GPS – 10 MHz -48 Hz offset – zero beat
The DDS sine in the upper trace is zero-beat against the GPS reference in the lower trace. There’s no hardware interlock, but they’re dead stationary during whatever DDS output step produces exactly 10.0000000 MHz. The temperature coefficient seems to be around 2.4 Hz/°C, so the merest whiff of air changes the frequency by more than 0.1 Hz.
It’s kinda like watching paint dry or a 3D printer at work, but it’s my paint: I like it a lot!
The Arduino source code as a GitHub Gist:
Arduino vs. Significant Figures: Useful 64-bit Fixed Point
Posted by Ed in Amateur Radio, Software on 2017-05-26
Devoting eight bytes to every fixed point number may be excessive, but having nine significant figures apiece for the integer and fraction parts pushes the frequency calculations well beyond the limits of the DDS hardware, without involving any floating point library routines. This chunk of code performs a few more calculations using the format laid out earlier and explores a few idioms that may come in handy later.
Rounding the numbers to a specific number of decimal places gets rid of the repeating-digit problem that turns 0.10 into 0.099999:
uint64_t RoundFixedPt(union ll_u TheNumber,unsigned Decimals) {
union ll_u Rnd;
Rnd.fx_64 = (One.fx_64 / 2) / (pow(10LL,Decimals));
TheNumber.fx_64 = TheNumber.fx_64 + Rnd.fx_64;
return TheNumber.fx_64;
}
That pretty well trashes the digits beyond the rounded place, so you shouldn’t display any more of them:
void PrintFixedPtRounded(char *pBuffer,union ll_u FixedPt,unsigned Decimals) {
char *pDecPt;
FixedPt.fx_64 = RoundFixedPt(FixedPt,Decimals);
PrintIntegerLL(pBuffer,FixedPt); // do the integer part
pBuffer += strlen(pBuffer); // aim pointer beyond integer
pDecPt = pBuffer; // save the point location
*pBuffer++ = '.'; // drop in the decimal point, tick pointer
PrintFractionLL(pBuffer,FixedPt);
if (Decimals == 0)
*pDecPt = 0; // 0 places means discard the decimal point
else
*(pDecPt + Decimals + 1) = 0; // truncate string to leave . and Decimals chars
}
Which definitely makes the numbers look prettier:
Tenth.fx_64 = One.fx_64 / 10; // Likewise, 0.1
PrintFixedPt(Buffer,Tenth);
printf("\n0.1: %s\n",Buffer);
PrintFixedPtRounded(Buffer,Tenth,9); // show rounded value
printf("0.1 to 9 dec: %s\n",Buffer);
TestFreq.fx_64 = RoundFixedPt(Tenth,3); // show full string after rounding
PrintFixedPt(Buffer,TestFreq);
printf("0.1 to 3 dec: %s (full string)\n",Buffer);
PrintFixedPtRounded(Buffer,Tenth,3); // show truncated string with rounded value
printf("0.1 to 3 dec: %s (truncated string)\n",Buffer);
0.1: 0.099999999
0.1 to 9 dec: 0.100000000
0.1 to 3 dec: 0.100499999 (full string)
0.1 to 3 dec: 0.100 (truncated string)
CtPerHz.fx_64 = -1; // Set up 2^32 - 1, which is close enough
CtPerHz.fx_64 /= 125 * MEGA; // divide by nominal oscillator
PrintFixedPt(Buffer,CtPerHz);
printf("\nCt/Hz = %s\n",Buffer);
printf("Rounding: \n");
for (int d = 9; d >= 0; d--) {
PrintFixedPtRounded(Buffer,CtPerHz,d);
printf(" %d: %s\n",d,Buffer);
}
Ct/Hz = 34.359738367
Rounding:
9: 34.359738368
8: 34.35973837
7: 34.3597384
6: 34.359738
5: 34.35974
4: 34.3597
3: 34.360
2: 34.36
1: 34.4
0: 34
Multiplying two scaled 64-bit fixed-point numbers should produce a 128-bit result. For all the values we (well, I) care about, the product will fit into a 64-bit result, because the integer parts will always multiply out to less than 232 and we don’t care about more than 32 bits of fraction. This function multiplies two fixed point numbers of the form a.b × c.d by adding up the partial products thusly: ac + bd + ad + bc. The product of the integers ac won’t overflow 32 bits, the cross products ad and bc will always be slightly less than their integer factors, and the fractional product bd will always be less than 1.0.
Soooo, just multiply ’em out as 64-bit integers, shift the products around to align the appropriate parts, and add up the pieces:
uint64_t MultiplyFixedPt(union ll_u Mcand, union ll_u Mplier) {
union ll_u Result;
Result.fx_64 = ((uint64_t)Mcand.fx_32.high * (uint64_t)Mplier.fx_32.high) << 32; // integer parts (clear fract)
Result.fx_64 += ((uint64_t)Mcand.fx_32.low * (uint64_t)Mplier.fx_32.low) >> 32; // fraction parts (always < 1)
Result.fx_64 += (uint64_t)Mcand.fx_32.high * (uint64_t)Mplier.fx_32.low; // cross products
Result.fx_64 += (uint64_t)Mcand.fx_32.low * (uint64_t)Mplier.fx_32.high;
return Result.fx_64;
}
This may be a useful way to set magic numbers with a few decimal places, although it does require keeping the decimal point in mind:
TestFreq.fx_64 = (599999LL * One.fx_64) / 10; // set 59999.9 kHz differently
PrintFixedPt(Buffer,TestFreq);
printf("\nTest frequency: %s\n",Buffer);
PrintFixedPtRounded(Buffer,TestFreq,1);
printf(" round: %s\n",Buffer);
Test frequency: 59999.899999999
round: 59999.9
Contrary to what I thought, computing the CtPerHz coefficient doesn’t require pre-dividing both 232 and the oscillator by 2, thus preventing the former from overflowing a 32 bit integer. All you do is knock the numerator down by one little itty bitty count you’ll never notice:
CtPerHz.fx_64 = -1; // Set up 2^32 - 1, which is close enough
CtPerHz.fx_64 /= 125 * MEGA; // divide by nominal oscillator
PrintFixedPt(Buffer,CtPerHz);
printf("\nCt/Hz = %s\n",Buffer);
Ct/Hz = 34.359738367
That’s also the largest possible fixed-point number, because unsigned:
TempFX.fx_64 = -1;
PrintFixedPt(Buffer,TempFX);
printf("Max fixed point: %s\n",Buffer);
Max fixed point: 4294967295.999999999
With nine.nine significant figures in the mix, tweaking the 125 MHz oscillator to within 2 Hz will work:
Oscillator tune: CtPerHz Oscillator: 125000000.00 -10 -> 34.359741116 -9 -> 34.359741116 -8 -> 34.359740566 -7 -> 34.359740566 -6 -> 34.359740017 -5 -> 34.359740017 -4 -> 34.359739467 -3 -> 34.359739467 -2 -> 34.359738917 -1 -> 34.359738917 +0 -> 34.359738367 +1 -> 34.359738367 +2 -> 34.359737818 +3 -> 34.359737818 +4 -> 34.359737268 +5 -> 34.359737268 +6 -> 34.359736718 +7 -> 34.359736718 +8 -> 34.359736168 +9 -> 34.359736168 +10 -> 34.359735619
So, all in all, this looks good. The vast number of strings in the test program bulk it up beyond reason, but in actual practice I think the code will be smaller than the equivalent floating point version, with more significant figures. Speed isn’t an issue either way, because the delays waiting for the crystal tester to settle down at each frequency step should be larger than any possible computation.
The results were all verified with my trusty HP 50g and HP-15C calculators, both of which wipe the floor with any other way of handling mixed binary / hex / decimal arithmetic. If you do bit-wise calculations, even on an irregular basis, get yourself a SwissMicro DM16L; you can thank me later.
The Arduino source code as a GitHub Gist:
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