GuitarModels/GuitarFretboards.scad

// Fender standard is 25.5"
Guitar_Scale_Length_In = 25.5;
// Convert to mm (1" = 25.4mm)
//Guitar_Scale_Length_mm = Guitar_Scale_Length_In * 25.4;
// This conversion ends up with 647.7mm, but 648mm has nice round number 865mm on the -5 fret too! Regular P-bass is 864mm
Guitar_Scale_Length_mm = 648;
// Extending the Strat by 5 frets gives a P-Bass
Bass_Fret = -5;

PBass_Nut_Width_In = 1.625; // (43mm)
JBass_Nut_Width_In = 1.5;   // (38mm)
Strat_Nut_Width_In = 1.65;  // (42mm)

function fret_scale_length(n) = Guitar_Scale_Length_mm * 2^(-n/12);
function lerp(start, end, amount) = start + (end-start)*amount;

echo(str("Guitar scale length is ", fret_scale_length(0), "mm"));
echo(str("Bass scale length is ", fret_scale_length(Bass_Fret), "mm"));

// Our modules need to fit in our 25x20cm build area
// This can be obtained by [-5,0), [0,7), [7,19), [19,bridge] modules.

module radiused_chord(w, r, points=12) {
    // w <= abs(r)*2
    // Negative r possible for mirroring across y-axis
    angle = asin(0.5*w/r);
    angles = [
        for (i = [0:points-1])
        let (f = -0.5 + i/(points-1))
        f * 2 * angle
    ];
    x0 = r*cos(angle);
    coords = [
        for (th = angles)
        let (
            x = r*cos(th) - x0,
            y = r*sin(th)
        )
        [x,y]
    ];
    polygon(coords);
}

module c_text(s, size)
    text(s, size=size, halign="center", valign="center", font="Noto Sans");

epsilon = 0.0001;
module to3d()
{linear_extrude(epsilon) children();}

nut_width = 38;
bridge_width = nut_width + 40;

fretboard_radius = 5.5*25.4;
neck_radius = 20;
color("red")
rotate([0,90]) hull(){
translate([0,0,fret_scale_length(Bass_Fret)/4])
    to3d() radiused_chord(lerp(bridge_width, nut_width, 1/4), -fretboard_radius);
translate([0,0,fret_scale_length(Bass_Fret)])
    to3d() radiused_chord(nut_width, -fretboard_radius);
}
// color("blue")
// rotate([0,90]) hull(){
// translate([0,-bridge_width/2,0])
//     cube([20, bridge_width, 1]);
// translate([0,0,fret_scale_length(Bass_Fret)])
//     to3d() scale([0.25,1]) radiused_chord(nut_width, neck_radius);
// }

module frets_and_markers(min_fret=-5, max_fret=36, width=bridge_width) {
    // Fret wire placeholder model
    for (x = [for (i = [min_fret:max_fret]) fret_scale_length(i)])
        translate([x, -width/2, 0])
        cube([1, width, 12]);

    // Fret dots
    for (octave = [0:3])
        for (fret = [3, 5, 7, 9]) {
        i = fret + (octave*12);
        if (i > min_fret && i <= max_fret)
            translate([(fret_scale_length(i)+fret_scale_length(i-1))/2,0,0])
            //cylinder(h=10, r=4);
            linear_extrude(10) c_text(str(fret), size=8);
    }
    // Octave markers
    for (i = [0, 12, 24, 36]) if (i > min_fret && i <= max_fret) hull(){
        translate([(fret_scale_length(i)+fret_scale_length(i-1))/2,20,0]) cylinder(h=10, r=3);
        translate([(fret_scale_length(i)+fret_scale_length(i-1))/2,-20,0]) cylinder(h=10, r=1);
    }
    // Bass extension
    if (min_fret < -1)
    for (i = [min_fret+1:-1])
        translate([(fret_scale_length(i)+fret_scale_length(i-1))/2,0,0])
        linear_extrude(10) c_text(str(i), size=12);
}

Module_Length = 220;  // Printer can do up to 250mm, the bass fret run is 217mm. Don't forget overlapping joins!
Module_Overhang = 20;
Module_Bridge_Offset = -15; //80 240

module Connector() {
    translate([0,0,-15])
    linear_extrude(10)
    polygon([[0,5],[0,-5],[Module_Overhang,-15],[Module_Overhang,15]]);
}

module Body(thickness=20, width=90) {
    color("blue", 0.5)
    translate([Module_Bridge_Offset, -width/2, -thickness])
    cube([Module_Length, width, thickness]);
    frets_and_markers(20, 24);
    translate([Module_Bridge_Offset+Module_Length, 0, 0]) Connector();

    // Bridge
    translate([-20, -bridge_width/2, 3])
    cube([20, bridge_width, 10]);
}

module Neck1(thickness=18, width=70) {
    color([0,0.5,1], 0.5)
    translate([Module_Bridge_Offset+Module_Length, -width/2, -thickness])
    cube([Module_Length, width, thickness]);
    frets_and_markers(8, 20);
    translate([Module_Bridge_Offset+Module_Length*2, 0, 0]) Connector();
}

module Neck2(thickness=17, width=60) {
    color([0.5,0,1], 0.5)
    translate([Module_Bridge_Offset+Module_Length*2, -width/2, -thickness])
    cube([Module_Length, width, thickness]);
    frets_and_markers(1, 7);
    translate([Module_Bridge_Offset+Module_Length*3, 0, 0]) Connector();
}

module Neck_Bass(thickness=16, width=40) {
    color([1,0,0.5], 0.5)
    translate([Module_Bridge_Offset+Module_Length*3, -width/2, -thickness])
    cube([Module_Length+Module_Overhang, width, thickness]);
    frets_and_markers(-5, 0);
}


// Structural Aluminium
density_6063 = 2.7;  // 6063 alloy is around 2.7g/cm3
echo(str("Weight of one 12mm x 3mm x 1m bar is ", density_6063*1.2*0.3*100, "g"));
echo(str("Weight of three 12mm x 3mm x 1m bar is ", density_6063*3.6*0.3*100, "g"));
echo(str("Weight of one 12x3 and two 10x3 x 1m bars is ", density_6063*3.2*0.3*100, "g"));
echo(str("Weight of one 12mm x 12mm x 1.5mm x 1m channel is roughly ", density_6063*1.2*0.15*100*3, "g"));
echo(str("Weight of one 16mm x 16mm x 1.5mm x 1m channel is roughly ", density_6063*1.6*0.15*100*3, "g"));

module Parallel_Bars(spacing=18, x0=-80) {
    // for (y = [-1.5-spacing, -1.5, -1.5+spacing])
    //     translate([x0, y, -12]) cube([1000,3,12]);  // 12mm x 3mm bar, 1m length
    translate([x0, -1.5, -12]) cube([1000,3,12]);  // 12mm x 3mm bar, 1m length
    for (y = [-1.5-spacing, -1.5+spacing])
        translate([x0, y, -10]) cube([1000,3,10]);  // 12mm x 3mm bar, 1m length
}
module Alu_Channel(x0=-80) {
    thickness = 1.5;
    y0 = -thickness/2;
    //12x12x1.5 channel
    translate([x0, -6, -thickness]) cube([1000, 12, thickness]);
    for (y = [y0-6, y0+6])
        translate([x0, y, -12]) cube([1000, thickness, 12]);
}

// frets_and_markers(-5, 29);
Body(); Neck1(); Neck2();
Neck_Bass();
Parallel_Bars();

translate([0,150,0]) Body();
translate([0,250,0]) Neck1();
translate([0,150,0]) Neck2();
translate([0,250,0]) Neck_Bass();

translate([0,-150,0]) {
    Body(); Neck1(); Neck2();
    Alu_Channel();
}
Initial commit 2023-06-13 21:21:33 +09:30			`// Fender standard is 25.5"`
			`Guitar_Scale_Length_In = 25.5;`
			`// Convert to mm (1" = 25.4mm)`
			`//Guitar_Scale_Length_mm = Guitar_Scale_Length_In * 25.4;`
			`// This conversion ends up with 647.7mm, but 648mm has nice round number 865mm on the -5 fret too! Regular P-bass is 864mm`
			`Guitar_Scale_Length_mm = 648;`
			`// Extending the Strat by 5 frets gives a P-Bass`
			`Bass_Fret = -5;`

			`PBass_Nut_Width_In = 1.625; // (43mm)`
			`JBass_Nut_Width_In = 1.5; // (38mm)`
			`Strat_Nut_Width_In = 1.65; // (42mm)`

			`function fret_scale_length(n) = Guitar_Scale_Length_mm * 2^(-n/12);`
			`function lerp(start, end, amount) = start + (end-start)*amount;`

			`echo(str("Guitar scale length is ", fret_scale_length(0), "mm"));`
			`echo(str("Bass scale length is ", fret_scale_length(Bass_Fret), "mm"));`

			`// Our modules need to fit in our 25x20cm build area`
			`// This can be obtained by [-5,0), [0,7), [7,19), [19,bridge] modules.`

			`module radiused_chord(w, r, points=12) {`
			`// w <= abs(r)*2`
			`// Negative r possible for mirroring across y-axis`
			`angle = asin(0.5*w/r);`
			`angles = [`
			`for (i = [0:points-1])`
			`let (f = -0.5 + i/(points-1))`
			`f * 2 * angle`
			`];`
			`x0 = r*cos(angle);`
			`coords = [`
			`for (th = angles)`
			`let (`
			`x = r*cos(th) - x0,`
			`y = r*sin(th)`
			`)`
			`[x,y]`
			`];`
			`polygon(coords);`
			`}`

			`module c_text(s, size)`
			`text(s, size=size, halign="center", valign="center", font="Noto Sans");`

			`epsilon = 0.0001;`
			`module to3d()`
			`{linear_extrude(epsilon) children();}`

			`nut_width = 38;`
			`bridge_width = nut_width + 40;`

			`fretboard_radius = 5.5*25.4;`
			`neck_radius = 20;`
			`color("red")`
			`rotate([0,90]) hull(){`
			`translate([0,0,fret_scale_length(Bass_Fret)/4])`
			`to3d() radiused_chord(lerp(bridge_width, nut_width, 1/4), -fretboard_radius);`
			`translate([0,0,fret_scale_length(Bass_Fret)])`
			`to3d() radiused_chord(nut_width, -fretboard_radius);`
			`}`
			`// color("blue")`
			`// rotate([0,90]) hull(){`
			`// translate([0,-bridge_width/2,0])`
			`// cube([20, bridge_width, 1]);`
			`// translate([0,0,fret_scale_length(Bass_Fret)])`
			`// to3d() scale([0.25,1]) radiused_chord(nut_width, neck_radius);`
			`// }`

			`module frets_and_markers(min_fret=-5, max_fret=36, width=bridge_width) {`
			`// Fret wire placeholder model`
			`for (x = [for (i = [min_fret:max_fret]) fret_scale_length(i)])`
			`translate([x, -width/2, 0])`
			`cube([1, width, 12]);`

			`// Fret dots`
			`for (octave = [0:3])`
			`for (fret = [3, 5, 7, 9]) {`
			`i = fret + (octave*12);`
			`if (i > min_fret && i <= max_fret)`
			`translate([(fret_scale_length(i)+fret_scale_length(i-1))/2,0,0])`
			`//cylinder(h=10, r=4);`
			`linear_extrude(10) c_text(str(fret), size=8);`
			`}`
			`// Octave markers`
			`for (i = [0, 12, 24, 36]) if (i > min_fret && i <= max_fret) hull(){`
			`translate([(fret_scale_length(i)+fret_scale_length(i-1))/2,20,0]) cylinder(h=10, r=3);`
			`translate([(fret_scale_length(i)+fret_scale_length(i-1))/2,-20,0]) cylinder(h=10, r=1);`
			`}`
			`// Bass extension`
			`if (min_fret < -1)`
			`for (i = [min_fret+1:-1])`
			`translate([(fret_scale_length(i)+fret_scale_length(i-1))/2,0,0])`
			`linear_extrude(10) c_text(str(i), size=12);`
			`}`

			`Module_Length = 220; // Printer can do up to 250mm, the bass fret run is 217mm. Don't forget overlapping joins!`
			`Module_Overhang = 20;`
			`Module_Bridge_Offset = -15; //80 240`

			`module Connector() {`
			`translate([0,0,-15])`
			`linear_extrude(10)`
			`polygon([[0,5],[0,-5],[Module_Overhang,-15],[Module_Overhang,15]]);`
			`}`

			`module Body(thickness=20, width=90) {`
			`color("blue", 0.5)`
			`translate([Module_Bridge_Offset, -width/2, -thickness])`
			`cube([Module_Length, width, thickness]);`
			`frets_and_markers(20, 24);`
			`translate([Module_Bridge_Offset+Module_Length, 0, 0]) Connector();`

			`// Bridge`
			`translate([-20, -bridge_width/2, 3])`
			`cube([20, bridge_width, 10]);`
			`}`

			`module Neck1(thickness=18, width=70) {`
			`color([0,0.5,1], 0.5)`
			`translate([Module_Bridge_Offset+Module_Length, -width/2, -thickness])`
			`cube([Module_Length, width, thickness]);`
			`frets_and_markers(8, 20);`
			`translate([Module_Bridge_Offset+Module_Length*2, 0, 0]) Connector();`
			`}`

			`module Neck2(thickness=17, width=60) {`
			`color([0.5,0,1], 0.5)`
			`translate([Module_Bridge_Offset+Module_Length*2, -width/2, -thickness])`
			`cube([Module_Length, width, thickness]);`
			`frets_and_markers(1, 7);`
			`translate([Module_Bridge_Offset+Module_Length*3, 0, 0]) Connector();`
			`}`

			`module Neck_Bass(thickness=16, width=40) {`
			`color([1,0,0.5], 0.5)`
			`translate([Module_Bridge_Offset+Module_Length*3, -width/2, -thickness])`
			`cube([Module_Length+Module_Overhang, width, thickness]);`
			`frets_and_markers(-5, 0);`
			`}`


			`// Structural Aluminium`
			`density_6063 = 2.7; // 6063 alloy is around 2.7g/cm3`
			`echo(str("Weight of one 12mm x 3mm x 1m bar is ", density_60631.20.3*100, "g"));`
			`echo(str("Weight of three 12mm x 3mm x 1m bar is ", density_60633.60.3*100, "g"));`
			`echo(str("Weight of one 12x3 and two 10x3 x 1m bars is ", density_60633.20.3*100, "g"));`
			`echo(str("Weight of one 12mm x 12mm x 1.5mm x 1m channel is roughly ", density_60631.20.151003, "g"));`
			`echo(str("Weight of one 16mm x 16mm x 1.5mm x 1m channel is roughly ", density_60631.60.151003, "g"));`

			`module Parallel_Bars(spacing=18, x0=-80) {`
			`// for (y = [-1.5-spacing, -1.5, -1.5+spacing])`
			`// translate([x0, y, -12]) cube([1000,3,12]); // 12mm x 3mm bar, 1m length`
			`translate([x0, -1.5, -12]) cube([1000,3,12]); // 12mm x 3mm bar, 1m length`
			`for (y = [-1.5-spacing, -1.5+spacing])`
			`translate([x0, y, -10]) cube([1000,3,10]); // 12mm x 3mm bar, 1m length`
			`}`
			`module Alu_Channel(x0=-80) {`
			`thickness = 1.5;`
			`y0 = -thickness/2;`
			`//12x12x1.5 channel`
			`translate([x0, -6, -thickness]) cube([1000, 12, thickness]);`
			`for (y = [y0-6, y0+6])`
			`translate([x0, y, -12]) cube([1000, thickness, 12]);`
			`}`

			`// frets_and_markers(-5, 29);`
			`Body(); Neck1(); Neck2();`
			`Neck_Bass();`
			`Parallel_Bars();`

			`translate([0,150,0]) Body();`
			`translate([0,250,0]) Neck1();`
			`translate([0,150,0]) Neck2();`
			`translate([0,250,0]) Neck_Bass();`

			`translate([0,-150,0]) {`
			`Body(); Neck1(); Neck2();`
			`Alu_Channel();`
			`}`