# Music on CNC

#### PSY-Gangnam Style

It’s possible to compute a combination of (distance, feed-rate) along an axis that will cause the stepper motor for that axis to spin at an exact frequency corresponding to a musical note. With a little vector magic, the same can be done for (x, y, z, feed-rate) to produce chords as the machine follows a 3D line through space.

##### How This Works:

We have code G1 [pos]x F[feed-rate] for linear interpolation at a specific feed-rate. Thus need to convert between feed-rate in IPM and frequency in Hz (steps per inch or inches per step). My machine as currently configured is 36000 steps/in, so if we wanted it to play middle A (440Hz) (440*60 = 26400 steps/min) we would want to move along a single axis at feed-rate (26400/36000 = 0.7333..) IPM.
or more generally, (freq/600) IPM.

Here are the frequencies for one octave. The formula to convert semitones (notes) to their actual frequencies is

f = fRef*2^(x/12)

where fRef is an arbitrarily chosen reference frequency corresponding to a specific note, and x is the number of semitones difference between the note you want and the reference. Middle A (440Hz) is as good a reference note as any, and its MIDI note number is 69, so the formula to calculate frequency for any MIDI note number becomes:

f = 440*2^((x-69)/12)

C4 = 261.63Hz
D4 = 293.66
E4 = 329.63
F4 = 349.23
G4 = 392.00
A4 = 440.00
B4 = 493.88
C5 = 523.25

And the G-code with the resulting feed-rates to play this scale on my machine:

G1 X1 F0.43605
G1 X2 F0.48943333333333333333333333333333
G1 X3 F0.54938333333333333333333333333333
G1 X4 F0.58205
G1 X5 F0.65333333333333333333333333333333
G1 X6 F0.73333333333333333333333333333333
G1 X7 F0.82313333333333333333333333333333
G1 X8 F0.87208333333333333333333333333333

Unfortunately, our note duration is now frequency-dependent. If we wanted it to play for 1 minute, we should make the distance equal to the feedrate in IPM (or 1/60 of that to play for 1 second, etc.). Easy-peasy so far.

Now let’s complicate things a bit. Suppose we want to play 2 or 3 notes at once. G-code linear interpolation scheme is that in, say, an XYZ move, all the axes arrive at the same time. Feedrate is the speed the tool moves along this *vector*, not the speed of the fastest/arbitrary axis. In other words, you cannot specify individual feedrates for the (x,y,z) axis moves, only one for the resulting vector as a whole. So, since the vector that results from adding 2 ore more axis moves will always be longer than either of the individual axis moves (for the 2-axis case, think the hypotenuse of a right triangle) the feedrate we set will be faster than the highest note, and will depend on the individual notes and their contributions to that vector.

Assume the bog-standard C-E-G chord. To play each on its own for 1 second…

G1 X0.0072675 F0.43605 ; move this distance
G1 X0.0164238 F0.54938 ; move 0.009156333…
G1 X0.0273126 F0.65333 ; move 0.010888833…

…but we want to combine these into a single (x,y,z) vector at a single feedrate.
The vector is obviously (0,0,0 to .00726, .00915, .01088), and its length is given by sqrt(x^2 + y^2 + z^2). Remember we are playing all three notes for the same length of time. The vector has lengthened, but the desired playing time has not, so we need to choose the feedrate for this new distance that yields the same travel time.

Regardless of how the length or rate changes, the (x,y,z) components remain proportional to one another. Just pick one of the individual axes/notes as a reference, compare the final vector length to the length of the reference note and bump the feedrate proportionally to the change in length. In this case we arbitrarily select the highest note as the reference, and the ratio of the final feedrate (unknown) to the reference feedrate (known) should equal the ratio of the 3D vector length (known) to the reference length (known). It’s almost too easy!

3D Vector length: 0.015975658808286373765422932349422

Feedrate: (newlength/oldlength) * oldfeed

= 1.4671598699591015644580950363551 * 0.65333

= 0.9585395578403798251074072301019

G1 X0.0072675 Y0.009156333 Z0.010888833 F0.95853955

Just remember that *any* change of any note requires computing a fresh new vector, so long notes will have to be split up wherever another concurrent note changes.

# Solder Fume extractor

This is a computer cooling fan, which is driven by 555 timer at 12V, the blue thing is the pot to vary speed of the motor.

# Laptop Cooler

All you need is:
3 foot long 1/2″ diameter PVC pipe,
4 90 degree elbow
2 cups/caps that will close the end of the pipe
Measuring tape
saw
drill
spade drill bits(not essential but good to have)
If you plan to use a fan these are the extra things that you will need
Cooling fan
USB male plug
wires
shrink tube
solder iron

I’ve add some pictures so can get the idea.
There are three pipes, 1 is along the longer(pipe along the scree of laptop),2( at the sides of latop, same length)
First measure the distance between the base pad of the laptop along the screen,
cut the pipe according to the dimension, also take in consideration the offset distance of the elbows,
To be safe cut exactly to the length measured and add the elbows and cut it so that the rubber pads sit exactly on the elbow.
Cut two small pieces of pipe to attach the two elbows on both sides.
Now cut the remaining pipe into half and attach it to the elbow.
Attach the end caps.
Make sure that all the rubber pads are on the pipe.
The laptop might slip so be CAREFUL!
To stop this with the laptop on mark 4 place where the rubber pads  touch the pipe.
Drill a hole big enough so the pad can sink in the pipe.
In some laptop the rubber pads might be rectangular in shape, in that case use a file to make space for the pad.