Posts Tagged Arduino
MOSFET rDS PCB
Posted by Ed in Machine Shop, Electronics Workbench on 23-February-2012
This one came out surprisingly well, apart from the total faceplant with that resistor. With any luck, it’ll measure MOSFET on-state drain resistance over temperature for an upcoming Circuit Cellar column; it’s a honkin’ big Arduino shield, of course.
Drilled holes on the Sherline using the relocated tool height switch:
rDS Tester - drilled PCB
Front copper, after etching & silver plating:
rDS Tester - etched front
Back copper, ditto:
rDS Tester - etched rear
I think I can epoxy the resistor kinda-sorta in the right spot without having to drill through the PCB into the traces. Maybe nobody will notice?
The traces came out fairly well, although I had to do both the top and bottom toner transfer step twice to get good adhesion. Sometimes it works, sometimes it doesn’t, and I can’t pin down any meaningful differences in the process.
And it really does have four distinct ground planes. The upper right carries 8 A PWM Peltier current, the lower right has 3 A drain current, the rectangle in the middle is the analog op-amp circuitry tied to the Analog common, and surrounding that is the usual Arduino bouncy digital ground stuff. The fact that Analog common merges with digital ground on the Arduino PCB is just the way it is…
Thermistor Linearization
Posted by Ed in Electronics Workbench on 9-February-2012
Faced with the need to measure heatsink temperature in an Arduino project and being unwilling to putz around with a MAX6675 thermocouple amp, I found a bag of thermistors in the heap. Unlike most surplus, the bag pedigreed them as Semitec 103CT-4, which led to some relevant parameters:
- T0 = 25 °C
- R0 = 10 kΩ
- B = 3270 K
The equation for a thermistor’s resistance at a given temperature (in K, not °C) is:
R = R0 * e(B/T - B/T0)
The canonical Arduino thermistor circuit uses a series resistor with a value equal to R0:
Thermistor Linearization - Rseries
Setting Rseries = 10 KΩ and applying a bit of spreadsheet-fu produces this:
Thermistor Linearization - Rseries - Graph
Getting within +2 °C /-1 °C over -20 °C to 60 °C isn’t all that bad, but … I wondered whether there might be an easy way to get better linearization. The heatsink temperature will range from about -10 °C to 60 °C (yes, there will be a Peltier cooler involved), so the range is a bit broader than usual.
A bit of diligent rummaging turned up that description, which led to US Patent 3,316,765 from back in 1967, which teaches the concept of two different thermistors, one for low temperatures and one for high temperatures, with some resistive blending:
Patent 3316765 Fig 3
The patent includes the claim of many different thermistors, each with a series resistor, to cover a much broader temperature range.
Given a bag of identical thermistors, I wondered what might be possible. A bit more spreadsheet-fu produced this:
Thermistor Linearization - Dual Thermistors - Graph
Which corresponds to this sketch, with Rseries = 6.2 kΩ, R1 = 27 kΩ, and R2 = 0.0:
Thermistor Linearization - Dual Thermistors
All in all, a nicely centered ±1 °C error from -15 °C to +60 °C can’t be beat. The output voltage even spans 0.13 to 0.71 of Vcc, about 9 of the available 10 ADC bits.
Those two resistors came from hand-tweaking with standard values, so it’s not like there’s a genetic algorithm involved. The value of Rseries wants to be a bit below the parallel combination of the two branches near 30 °C and R1 seems happiest around the 0 °C thermistor resistance. I vaguely thought about using a multivariable solver, but what’s the point?
The result seems good enough that I didn’t try three thermistors. T2, the one with R2=0, already handles the high temperature range and the low end is fine, so it seems there’s not much to be gained. If you had a stash of different thermistors and knew their characteristics, then the results would be different.
Admittedly, one could program the actual logarithmic equation to unbend a single thermistor’s voltage into temperature, but I must kludge up a thermistor mount anyway, so why not entomb two thermistors and an SMD resistor, then use a linear fit? It’s not like fancy math will give the whole lashup any greater accuracy.
The spreadsheet may be of interest. It started out as an OpenOffice spreadsheet, but WordPress doesn’t permit *.ods files, soooo it’s in MS Excel format.
Arduino Case
Posted by Ed in Electronics Workbench, Machine Shop on 6-July-2011
The base of that case makes a good protector to keep an Arduino board out of the conductive clutter on a typical electronics bench. I stopped the printer shortly after it finished the bosses atop the mounting posts:
Arduino case - base on build platform
That yellow filament means I can’t lose it!
Stepper Sync Wheel: Group Sync
Posted by Ed in Electronics Workbench on 22-June-2011
A small tweak to that code produces a sync pulse for each full sine wave of microstepping current, aligned with the step pulses. The sync pulse occurs on the rising edge of the current waveform (because I set it up that way) and has 50% duty cycle to allow triggering at either zero-current microstep.
Then pix like this happen:
Microstepping Group Sync
The traces:
- top = 1/group sync
- middle = winding current at 500 mA/div
- bottom = step pulse, 1/microstep
The big jump just before the zero-current microstep on the decreasing-current sides of the sine wave indicates that it’s hard to get all the current out of the windings at 12 V. A detail view of those steps shows that the current is 50% higher than it should be at the start of the zero-current microstep, having completely missed the last microstep:
Decreasing Current
Which, of course, is why I’m doing all this: to explore that kind of behavior.
You may find the generated sync pulses are off by ±1 microstep from the expected start of the zero-current microstep, because the optical 1/rev signal threshold may line up perversely with the start of a microstep. You can twist the sync wheel just slightly on the shaft, but it’s pretty much a matter of shaking the dice to see if a better combination comes up. Doesn’t make any real difference to the scope triggering, though, as any stable sync alignment is as good as any other.
The code uses the 1/rev optical sync pulse once, to get the initial alignment, so whacking the wheel as it rotates may cause the generated sync pulses to skip a beat or twenty. The result remains stable, just at a different alignment.
One could argue that you really don’t need the 1/rev optical signal at all, but I find it comforting to use an absolute rotational reference to lock the pulses in (pretty nearly) the same place every time. If you’re stuck with an in-place motor, then you probably don’t have a 1/rev signal and you must wing it.
The Arduino source code:
// Stepper motor driver synchronization
// Ed Nisley KE4ZNU June 2011
//-- Stepper parameters
#define SYNC_OFFSET 8 // steps from 1/rev pulse to start of first 4-full-step group
#define FULL_STEPS_PER_REV 200
#define MICROSTEPPING 8
#define GROUPS_PER_REV (FULL_STEPS_PER_REV / 4)
#define STEPS_PER_GROUP (MICROSTEPPING * 4)
//-- Pin definitions, all of which depend on internal hardware: do *not* change
#define PIN_REV 2 // INT0 = positive 1/rev pulse from optical switch
#define PIN_STEP 5 // T1 = positive 1/step pulse from stepper driver
#define PIN_TRIGGER 9 // OC1A = positive trigger pulse to scope
//-- Trace outputs may be chosen freely
#define PIN_TRACE_A 10
#define PIN_TRACE_B 11
#define PIN_TRACE_C 12
#define PIN_LED 13 // standard Arduino LED
//---------------------
// State Variables
word PulseCounter;
//---------------------
// Useful routines
//--- Input & output pins
void TogglePin(char bitpin) {
digitalWrite(bitpin,!digitalRead(bitpin)); // toggle the bit based on previous output
}
//----------------
// Initializations
void setup() {
pinMode(PIN_REV,INPUT); // INT0 1/rev pulse from wheel
pinMode(PIN_STEP,INPUT); // T1 step pulse from stepper driver
pinMode(PIN_LED,OUTPUT);
digitalWrite(PIN_LED,LOW);
pinMode(PIN_TRACE_A,OUTPUT);
pinMode(PIN_TRACE_B,OUTPUT);
pinMode(PIN_TRACE_C,OUTPUT);
//--- Prepare Timer1 to count external stepper drive pulses
TCCR1B = B00001000; // Timer1: Mode 4 = CTC, TOP = OCR1A, clock stopped
pinMode(PIN_TRIGGER,OUTPUT); // OC1A to scope trigger
//-- Wait for rising edge of 1/rev pulse from optical switch
TCCR1A = B11000000; // COM1A set on compare
TCNT1 = 0; // ensure we start from zero
OCR1A = SYNC_OFFSET; // set step counter
while(!digitalRead(PIN_REV)) { // stall until 1/rev input rises
TogglePin(PIN_TRACE_A);
}
//-- Got it, fire up the timer to count steps to start of first group
TCCR1B |= B00000111; // enable clock from T1 pin, rising edge
digitalWrite(PIN_LED,HIGH); // show we got here
digitalWrite(PIN_TRACE_A,LOW);
while(!(TIFR1 & _BV(OCF1A))) { // wait for compare
digitalWrite(PIN_TRACE_B,digitalRead(PIN_STEP));
continue;
}
TIFR1 |= _BV(OCF1A); // clear match flag
//-- Scope sync pulse is now active, we can enter the main loop
}
//----------------
// The main event
void loop() {
//-- Scope sync pulse active
digitalWrite(PIN_LED,LOW); // show we got here
digitalWrite(PIN_TRACE_B,LOW);
//-- Set up for first half of the group, sync high -> low
TCCR1A = B10000000; // COM1A clear on compare
OCR1A = (STEPS_PER_GROUP / 2) - 1;
while(!(TIFR1 & _BV(OCF1A))) { // wait for compare
digitalWrite(PIN_TRACE_B,digitalRead(PIN_STEP));
continue;
}
TIFR1 |= _BV(OCF1A); // clear match flag
digitalWrite(PIN_TRACE_B,LOW);
//-- Set up for the second half, sync low -> high
TCCR1A = B11000000; // COM1A set on compare
OCR1A = (STEPS_PER_GROUP - (STEPS_PER_GROUP / 2)) - 1; // may be odd, so allow for that
while(!(TIFR1 & _BV(OCF1A))) { // wait for compare
digitalWrite(PIN_TRACE_B,digitalRead(PIN_STEP));
continue;
}
TIFR1 |= _BV(OCF1A); // clear match flag
digitalWrite(PIN_TRACE_B,LOW);
//-- Shut down counter and wait for end of 1/rev pulse
#if 0
TCCR1B &= ~B00000111; // turn off timer clock
while(digitalRead(PIN_REV)) { // stall until 1/rev pulse goes low again
TogglePin(PIN_TRACE_C);
}
digitalWrite(PIN_TRACE_B,LOW);
#endif
}
Stepper Sync Wheel: Current Waveform First Light
Posted by Ed in Electronics Workbench, Machine Shop on 20-June-2011
Eks loaned me a Tek AM503 Current Probe Amplifier, one of those gorgeous instruments that Just Works: a clamp-on DC to 50 MHz Hall Effect current meter. Because it’s electrically isolated from all the hideous electrical hash that surrounds any stepper motor driver circuit, it doesn’t see much of the garbage that pollutes any current sensor depending on a series resistance and a differential amplifier.
Which lets you take pix like this:
Stepper Test
From top to bottom:
- Generated 1/rev sync pulse
- Winding current at 200 mA/div (1 A peak current)
- Step drive pulses at about 3 rev/s
The initial ramp occupying the first third of each step comes from the motor’s L/R time constant coupled with the 9 V supply I was using. Back of the envelope: 2 mH / 2 Ω = 1 ms. With 8 V (9 V less MOSFET drops &c) applied, the initial slope = 8 V / 2 mH = 2500 A/s, so in 75 ms it rises 187 mA: close enough.
The small ripples show the A4988 chopping the current to maintain the proper value for each microstep.
Looks just like the pretty pictures in the datasheet, doesn’t it?
Thing-O-Matic: Thermal Runaway!
Posted by Ed in Electronics Workbench, Machine Shop on 7-June-2011
Well, it finally happened: the Extruder Controller jammed the extruder heater full on and the Thermal Core temperature went on an uncontrolled rise.
This changes the thermal runaway scenario from “It can’t happen here” to “Once is happenstance“.
I’d been tweaking an OpenSCAD model, slicing it, not liking the results shown in Skeinlayer, re-tweaking, re-slicing, and iterating around that loop for quite some time. When I figured I was close to having a good model & G-Code, I turned on the heaters to get the printer ready; heating from a cold start requires about 12 minutes due to the double aluminum build plates and hulking cartridge heater adapters.
I made several (well, many) more iterations through OpenSCAD and slicing, flipped to the Control Panel, and discovered the Thermal Core temperature was passing through 285 °C on the way up. Now, the temperature doesn’t rise abruptly, but it was already far higher than the original 210 °C setpoint; you cannot set an Extruder temperature over 260 °C (!) without passing through a confirmation dialog.
Oddly, the setpoint temperatures for both the Extruder and HBP showed 9 °C. The build platform was cooling off, as you would expect for a setpoint far below the actual temperature, but the Thermal Core heater was jammed on.
An LED indicator on the Z stage shows when the EC switches the cartridge heater on. That LED was lit, so I knew the EC had gone nuts: the heater was on, even though the Thermal Core temperature was far above the setpoint.
I passed up an opportunity for Science by punching the Emergency Shutdown button on the Thermal Lockout: the Thing-O-Matic went dark. Turned it back on, reconnected RepG, and ran a few yards of smoking hot filament out of the nozzle. Yes, the Thermal Core really was that hot… I ran the filament drive at 25 rev/min for 10 seconds and it sprayed filament like crazy.
The Thermal Lockout had not tripped, very much as expected. Back when I was figuring out where to mount the thermal switches, those measurements suggested that the Thermal Core would probably exceed 325 °C before the 100 °C NC switch at the top of the Thermal Rise opened. The Core hadn’t gotten close to that temperature, but it was on the way!
The 40 °C NO switch glued to the base of the filament drive had long since closed and lit the yellow LED, but even I agree that’s an absurdly low temperature for such a warning. I have no idea what the actual temperatures were, but I’m thinking of putting a pair of thermocouples in the obvious spots.
I’ve devoted considerable time and energy to eliminating erratic operation and glitchy behavior, to the extent that the printer has behaved flawlessly up to this point. Obviously, something glitched the Extruder Controller, which is basically an Arduino-class microcontroller monitoring two temperature sensors and driving two MOSFETs, while chatting with the Arduino Mega that lives under the Motherboard.
A power glitch will hard-reset the Mega (because I connected +Power Good to -Reset), but the (2.7, anyway) MB firmware has the disturbing property of not resetting the EC when it restarts. You can confirm this by turning the heaters on using the Control Panel, closing it, then blipping the Motherboard Reset button: the heaters remain on. I’ll connect +Power Good to the EC’s -Reset the next time I open the box.
The Thing-O-Matic worked fine (again) after the shutdown, but, as far as I’m concerned, all the effort I put into the Thermal Lockout on the Extruder Heaters has been justified. If the EC ran away once, it will run away again.
I don’t have an MBI MK6+ Thermal Core or their Safety Cutout Switch circuit, but a look at the schematic suggests a heads-up if you use that hardware. The Safety Cutout Switch has (IMO, anyway) several design flaws:
- The relay is not energized during normal operation. If it fails to energize when the thermal switch activates, the heater remains active.
- By design, the 12 V relay sees only 9 V when the thermal switch operates. The usual wiring resistance and MOSFET resistances, in combination with a sagging power supply, can reduce the available voltage below the relay’s 8.4 V must-operate voltage: it may not cut off the heater.
- The relay cannot operate when the ground connection in the Alarm cable isn’t connected, as is the case in a Cupcake without a matching E-Stop jack. In any printer, a disconnected Alarm cable or a broken ground wire will silently prevent the relay from operating.
I’m willing to be proven wrong on any of those points, but as nearly as I can tell, the cartridge heater in a MK6+ can operate with a completely non-functional “Safety Cutout” and you’ll never know there’s a problem. When installed exactly as directed and with the entire printer working properly, it’ll probably work… but if everything worked properly, you wouldn’t need it.
[Update: MBI recently issued a slipstream update that put the Safety Circuit at Rev B. The relay now attaches to the Extruder Controller MOSFET, thus eliminating the requirement for the Alarm cable's ground. However, the relay now sees the heater's high-current voltage drop on both terminals. Measure the actual voltage at the Safety Circuit's input terminals with both heaters running. If that voltage is less than 11.2 V, the relay must operate below its must-operate voltage in order to cut off the Extruder heater.]
The rant at the bottom of that post gave some features that I considered vital when I was designing the Thermal Lockout for my printer. I thought it went without saying that a safety circuit should fail safe: if the safety circuit does not operate, the protected equipment must not operate. As long as the Thermal Switch functions correctly, my Thermal Lockout will fail safe: an inoperative relay, a broken wire, a disconnected switch, or a weak power supply will prevent the printer from starting.
My circuit is not completely fail-safe, of course, but the most common problems cause a hard shutdown.
It really does matter…
I’m now thinking that a thermal switch on the heated build platform is a Good Thing. I suspect the solder will melt and the connector will fall off before melting the acrylic in an ABP or charring the plywood in an HBP, but it’d be interesting to test that assumption, wouldn’t it?
Thing-O-Matic: USB Power Backfeed Prevention
Posted by Ed in Electronics Workbench, Machine Shop on 11-March-2011
The Arduino Mega 2650 board used in the Thing-O-Matic gets its power from the +12 V ATX supply plugged into the TOM Motherboard. It will also automagically switch to +5 V from the USB connection when the +12 V external power Goes Away.
Come to find out that the Foxconn Atom I’m using doesn’t shut off the power to the USB ports when it’s “turned off”. That keeps the Arduino alive and, by a quirk of the circuitry, backfeeds +5 V into the +12 V supply, which makes its way back to the ATX power supply and keeps the fan running. Slowly, but it’s ticking over in there.
Rather than keep unplugging the USB cable, I added a diode in series with the Motherboard +12 V trace going to the Arduino connector:
USB backfeed prevention diode
The orange stuff is nail polish rejected by my Shop Assistant, which covers a slit gouged in the +12 V trace. The diode bridges the gouge and passes current only into the Arduino.
Any diode will do, as the next step in the +12 V supply chain is that poor overworked Arduino regulator responsible for shaving it down to +5 V. I used a good old 1N4001 and it’s perfectly happy.
[Update: the Arduino will remain powered up overnight, even with everything else turned off. When you turn the Thing-O-Matic on the next morning, pop the Reset button to get the Arduino's attention.]
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