/elec/propeller-clock : contents of notes at revision 40

: (revision 40)

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DISPLAY

The display is split up in to seconds, each with 5 subdivisions
(segments).  That's a total of 300 segments per revolution.

If the propeller spins at 2000RPM, that's 33.3 revolutions per second,
or 30ms (30,000μs) per revolution.  That means we'll be drawing 10,000
segments per second, which is 100μs per segment.  With a clock speed
of 16MHz, this is 1600 cycles per segment, which is plenty.


SCEMATIC NOTES

The diode (D14) across the fan's power connections is there because if
the power acrss the fan breaks (due to the unreliable nature of the
brushes), the motor in the fan has coils, which act like an inductor
and will produce a back EMF (a huge negative voltage across the power
connections) as the magnetic field collapses.  This won't be good for
the arduino and could cause sparks on the brushes.  The diode simply
shorts the negative voltage.

The capacitor (C1) and resistor (R14) are there to smooth the power
supply from the unreliable brushes.  The capacitor would discharge
fairly slowly (due to the resistance of the circuit), but will charge
very quickly.  Potentially, it will charge so quickly that it'll pull
too much current from the power supply.  So the resistor limits this.
Unfortunately, the resistor will also have a potentiometer effect
(with the resistence of the main circuit).  10Ω was chosen as a value
due to these rough workings: Lets say the arduino circuit takes 100mA.
if we aim to lose 1V across the resistor, that's 1V / 0.1A = 10Ω (from
V=IR).  The 100μF was a guess!  The problem with the capacitor is that
if it's can only hold a small charge, it won't be able to maintain a
reasonable charge when the power breaks.  If it's too large, it will
take ages to charge (and effectively short the power, save for the
resistor, while it charges).  100μF seemed like a good value,
according to dad!

39 by edam updated notes and scematic (adding capacitor+resistor and diode)	1	DISPLAY
	2
	3	The display is split up in to seconds, each with 5 subdivisions
	4	(segments). That's a total of 300 segments per revolution.
	5
	6	If the propeller spins at 2000RPM, that's 33.3 revolutions per second,
	7	or 30ms (30,000μs) per revolution. That means we'll be drawing 10,000
	8	segments per second, which is 100μs per segment. With a clock speed
	9	of 16MHz, this is 1600 cycles per segment, which is plenty.
	10
	11
	12	SCEMATIC NOTES
	13
	14	The diode (D14) across the fan's power connections is there because if
	15	the power acrss the fan breaks (due to the unreliable nature of the
	16	brushes), the motor in the fan has coils, which act like an inductor
	17	and will produce a back EMF (a huge negative voltage across the power
	18	connections) as the magnetic field collapses. This won't be good for
	19	the arduino and could cause sparks on the brushes. The diode simply
	20	shorts the negative voltage.
	21
	22	The capacitor (C1) and resistor (R14) are there to smooth the power
	23	supply from the unreliable brushes. The capacitor would discharge
	24	fairly slowly (due to the resistance of the circuit), but will charge
	25	very quickly. Potentially, it will charge so quickly that it'll pull
	26	too much current from the power supply. So the resistor limits this.
	27	Unfortunately, the resistor will also have a potentiometer effect
	28	(with the resistence of the main circuit). 10Ω was chosen as a value
	29	due to these rough workings: Lets say the arduino circuit takes 100mA.
	30	if we aim to lose 1V across the resistor, that's 1V / 0.1A = 10Ω (from
	31	V=IR). The 100μF was a guess! The problem with the capacitor is that
	32	if it's can only hold a small charge, it won't be able to maintain a
	33	reasonable charge when the power breaks. If it's too large, it will
	34	take ages to charge (and effectively short the power, save for the
	35	resistor, while it charges). 100μF seemed like a good value,
	36	according to dad!