Difference between revisions of "Team:Cambridge-JIC/Make Your Own js"
Line 200: | Line 200: | ||
ret += '</table>' | ret += '</table>' | ||
− | ret += '<br/><h4><strong>Assembly instructions:</strong></h4><br/><ul><li>Remove the lens from the Raspberry Pi camera. Using a pair of pliers (the kind with a ridged surface), grip the top circular plastic part of the lens and rotate counter-clockwise. We find it\'s easiest to grip the lens firmly and rotate the sensor, rather than the other way around.</li><li>Using super glue (we recommend Loctite\; apply with a brush) glue the following parts\:<ul><li>nuts (x3) on the bottom of the stage</li><li>legs (x1 large + x2 small)</li><li>screw caps (x3)</li><li>the 2 parts of the z axis together</li><li>RPi lens into lens holder</li><li>supporting axes (x2) into cube holder</li><li>washer into large leg (around the hole)</li></ul></li></ul>' | + | ret += '<br/><h4><strong>Assembly instructions:</strong></h4><br/><ul><li>Remove the lens from the Raspberry Pi camera. Using a pair of pliers (the kind with a ridged surface), grip the top circular plastic part of the lens and rotate counter-clockwise. We find it\'s easiest to grip the lens firmly and rotate the sensor, rather than the other way around.</li><li>Using super glue (we recommend Loctite\; apply with a brush) glue the following parts\:<ul><li>nuts (x3) on the bottom of the stage</li><li>legs (x1 large + x2 small)</li><li>screw caps (x3)</li><li>the 2 parts of the z axis together</li><li>RPi lens into lens holder</li><li>supporting axes (x2) into cube holder</li><li>washer into large leg (around the hole)</li>' |
+ | if(options[5] == 0) { | ||
+ | ret += '<li>screw holders (x3)</li>' | ||
+ | } | ||
+ | if(options[5] == 1) { | ||
+ | ret += '<li>motor holders (x3)</li>' | ||
+ | } | ||
+ | if(options[5] == 2) { | ||
+ | ret += '<li>motor holders (x3) or screw holders (x3) depending on whether motorised or manual mode is used</li>' | ||
+ | } | ||
+ | ret += '</ul></li></ul>' | ||
return $('<div>').html(ret) | return $('<div>').html(ret) |
Revision as of 14:44, 15 September 2015
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elem.append($('').text(this.question));
for (key in this.answers) {
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').text(this.question));
for (key in this.answers) {
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$(document).ready(function(){
q = new quiz('#cam-quiz');
step0 = new q.step("Tell us which options you'd like for your microscope.", {
1: "Okay!"
});
step1 = new q.step("Besides bright-field, do you need dark-field imaging?", {
0: "Yes",
1: "No"
});
step2 = new q.step("Do you need to image GFP fluorescence?", {
0: "Yes",
1: "No"
});
step3 = new q.step("Do you need to image RFP fluorescence?", {
0: "Yes",
1: "No"
});
step4 = new q.step("Do you need to image other fluorescent proteins, e.g. YFP?", {
0: "Yes",
1: "No"
});
step5 = new q.step("Do you want your microscope to be manual, motorised, or will you need to swap between both?", {
0: "Manual only",
1: "Motorised only",
2: "Both",
});
step6 = new q.step("Do you need your microscope to be fully battery-powered, e.g. for fieldwork?", {
0: "Yes",
1: "No"
});
final = function(options) {
window.location.href="#CC0";
ret = '<h3>Thanks!</h3>
Here\'s what you\'ll need\:
3D PRINTED COMPONENTS Number Part Cost per unit (GBP) STL file SCAD file 1 main stage 3 legs 2 side supports for z axis 1 z axis in 3 parts (vertical + horizontal + connector) 1 connecting ring bw z axes 1 3-legged camera holder 2 slide clips 1 bright-field cube '
if(options[1] == 0) {
ret += '1 dark-field tube in N parts '
}
if(options[2] == 0 && options[3] == 0 && options[4] == 0) {
ret += '3 epicubes 3 drawers for the excitation filters 3 drawers for the emission filters 3 drawers for the dichroic mirrors '
}
else if((options[2] == 0 && options[3] == 0) || (options[2] == 0 && options[4] == 0) || (options[3] == 0 && options[4] == 0)) {
ret += '2 epicubes 2 drawers for the excitation filters 2 drawers for the emission filters 2 drawers for the dichroic mirrors '
} else if(options[2] == 0 || options[3] == 0 || options[4] == 0) {
ret += '1 epicube 1 drawer for the excitation filter 1 drawer for the emission filter 1 drawer for the dichroic mirror '
}
if(options[5] == 0 || options[5] == 2) {
ret += '3 screw gears 3 manual gears 3 screw holders '
}
if(options[5] == 1 || options[5] == 2) {
ret += '3 screw gears for motors 3 motor holders '
}
if((options[5] == 1 || options[5] == 2) && options[6] == 1) {
ret += '1 battery holder for RPi '
}
if((options[5] == 1 || options[5] == 2) && options[6] == 0) {
ret += '2 battery holders for RPi '
}
if(options[6] == 0 && !(options[5] == 1 || options[5] == 2)) {
ret += '1 battery holder for RPi '
}
ret += '
'
ret += '
OFF-THE-SHELF COMPONENTS Number Part Cost per unit (GBP) Description/Provider ~5 bright-field LEDs ?? lenses 2 25 mm long M4 screws 1 40 mm long M4 screw 3 M4 nuts + washers 1 Raspberry Pi 2 Model B 1 Ralink RT5370 WiFi adapter 1 Arduino UNO with its USB B connector 1 breadboard 1 16GB micro SD card 1 20 ohm resistor 1 ethernet cable ?? insulated single-core wire '
if(options[2] == 0 && options[3] == 0 && options[4] == 0) {
ret += '3 RPi cameras 1 RPi ribbon cable comes with RPi camera '
}
else if((options[2] == 0 && options[3] == 0) || (options[2] == 0 && options[4] == 0) || (options[3] == 0 && options[4] == 0)) {
ret += '2 RPi cameras 1 RPi ribbon cable comes with RPi camera '
} else if(options[2] == 0 || options[3] == 0 || options[4] == 0) {
ret += '1 RPi camera 1 RPi ribbon cable comes with RPi camera '
}
if(options[2] == 0) {
ret += '~5 LEDs (GFP) 1 dichroic mirror (GFP) 1 excitation filter (GFP) 1 emission filter (GFP) '
}
if(options[3] == 0) {
ret += '~5 LEDs (RFP) 1 dichroic mirror (RFP) 1 excitation filter (RFP) 1 emission filter (RFP) '
}
if(options[4] == 0) {
ret += '~5 LEDs tailored to FP 1 dichroic mirror tailored to FP 1 excitation filter tailored to FP 1 emission filter tailored to FP '
}
if(options[5] == 1 || options[5] == 2) {
ret += '3 stepper motors 2 UNL2003A Darlington driver chips '
}
if((options[5] == 1 || options[5] == 2) && options[6] == 1) {
ret += '1 9V battery connector '
}
if((options[5] == 1 || options[5] == 2) && options[6] == 0) {
ret += '2 9V battery connectors '
}
if(options[6] == 0 && !(options[5] == 1 || options[5] == 2)) {
ret += '1 9V battery connector '
}
if(options[6] == 0) {
ret += '1 1 MoPi power board '
}
if(options[6] == 1) {
ret += '1 2A micro USB power cable '
}
ret += '
'
ret += '
Assembly instructions:
- Remove the lens from the Raspberry Pi camera. Using a pair of pliers (the kind with a ridged surface), grip the top circular plastic part of the lens and rotate counter-clockwise. We find it\'s easiest to grip the lens firmly and rotate the sensor, rather than the other way around.
- Using super glue (we recommend Loctite\; apply with a brush) glue the following parts\:
- nuts (x3) on the bottom of the stage
- legs (x1 large + x2 small)
- screw caps (x3)
- the 2 parts of the z axis together
- RPi lens into lens holder
- supporting axes (x2) into cube holder
- washer into large leg (around the hole)
'
if(options[5] == 0) {
ret += ' - screw holders (x3)
'
}
if(options[5] == 1) {
ret += 'motor holders (x3) '
}
if(options[5] == 2) {
ret += 'motor holders (x3) or screw holders (x3) depending on whether motorised or manual mode is used '
}
ret += ''
return $('').html(ret)
}
step0.bind(step1, [1]);
step1.bind(step2, [0]);
step1.bind(step2, [1]);
step2.bind(step3, [0]);
step2.bind(step3, [1]);
step3.bind(step4, [0]);
step3.bind(step4, [1]);
step4.bind(step5, [0]);
step4.bind(step5, [1]);
step5.bind(step6, [0]);
step5.bind(step6, [1]);
step5.bind(step6, [2]);
step6.bind(final, [0]);
step6.bind(final, [1]);
q.start(step0);
});
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for (var i=quiz.steps.length; --i>index;) { quiz.steps[i].elem.remove(); quiz.steps.pop(); }
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')
Here\'s what you\'ll need\:
'
ret += '
'
ret += '
motor holders (x3) '
motor holders (x3) or screw holders (x3) depending on whether motorised or manual mode is used '
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for (key in answers) { answer = answers[key]; this.answers[key] = { 'answer': answer, 'target': undefined }; } };
this.start = function(step) { index = this.steps.length; ref = { 'step': step, 'elem': step.elem(this, index), 'option': undefined }; this.steps.push(ref); this.elem.append(ref.elem); }; };
$(document).ready(function(){ q = new quiz('#cam-quiz');
step0 = new q.step("Tell us which options you'd like for your microscope.", { 1: "Okay!" }); step1 = new q.step("Besides bright-field, do you need dark-field imaging?", { 0: "Yes", 1: "No" }); step2 = new q.step("Do you need to image GFP fluorescence?", { 0: "Yes", 1: "No" }); step3 = new q.step("Do you need to image RFP fluorescence?", { 0: "Yes", 1: "No" }); step4 = new q.step("Do you need to image other fluorescent proteins, e.g. YFP?", { 0: "Yes", 1: "No" }); step5 = new q.step("Do you want your microscope to be manual, motorised, or will you need to swap between both?", { 0: "Manual only", 1: "Motorised only", 2: "Both", }); step6 = new q.step("Do you need your microscope to be fully battery-powered, e.g. for fieldwork?", { 0: "Yes", 1: "No" });
final = function(options) {
window.location.href="#CC0";ret = '<h3>Thanks!</h3>
Here\'s what you\'ll need\:
3D PRINTED COMPONENTS | ||||
---|---|---|---|---|
Number | Part | Cost per unit (GBP) | STL file | SCAD file |
1 | main stage | |||
3 | legs | |||
2 | side supports for z axis | |||
1 | z axis in 3 parts (vertical + horizontal + connector) | |||
1 | connecting ring bw z axes | |||
1 | 3-legged camera holder | |||
2 | slide clips | |||
1 | bright-field cube | |||
1 | dark-field tube in N parts | |||
3 | epicubes | |||
3 | drawers for the excitation filters | |||
3 | drawers for the emission filters | |||
3 | drawers for the dichroic mirrors | |||
2 | epicubes | |||
2 | drawers for the excitation filters | |||
2 | drawers for the emission filters | |||
2 | drawers for the dichroic mirrors | |||
1 | epicube | |||
1 | drawer for the excitation filter | |||
1 | drawer for the emission filter | |||
1 | drawer for the dichroic mirror | |||
3 | screw gears | |||
3 | manual gears | |||
3 | screw holders | |||
3 | screw gears for motors | |||
3 | motor holders | |||
1 | battery holder for RPi | |||
2 | battery holders for RPi | |||
1 | battery holder for RPi |
OFF-THE-SHELF COMPONENTS | |||
---|---|---|---|
Number | Part | Cost per unit (GBP) | Description/Provider |
~5 | bright-field LEDs | ||
?? | lenses | ||
2 | 25 mm long M4 screws | ||
1 | 40 mm long M4 screw | ||
3 | M4 nuts + washers | ||
1 | Raspberry Pi 2 Model B | ||
1 | Ralink RT5370 WiFi adapter | ||
1 | Arduino UNO with its USB B connector | ||
1 | breadboard | ||
1 | 16GB micro SD card | ||
1 | 20 ohm resistor | ||
1 | ethernet cable | ||
?? | insulated single-core wire | ||
3 | RPi cameras | ||
1 | RPi ribbon cable | comes with RPi camera | |
2 | RPi cameras | ||
1 | RPi ribbon cable | comes with RPi camera | |
1 | RPi camera | ||
1 | RPi ribbon cable | comes with RPi camera | |
~5 | LEDs (GFP) | ||
1 | dichroic mirror (GFP) | ||
1 | excitation filter (GFP) | ||
1 | emission filter (GFP) | ||
~5 | LEDs (RFP) | ||
1 | dichroic mirror (RFP) | ||
1 | excitation filter (RFP) | ||
1 | emission filter (RFP) | ||
~5 | LEDs | tailored to FP | |
1 | dichroic mirror | tailored to FP | |
1 | excitation filter | tailored to FP | |
1 | emission filter | tailored to FP | |
3 | stepper motors | ||
2 | UNL2003A Darlington driver chips | ||
1 | 9V battery connector | ||
2 | 9V battery connectors | ||
1 | 9V battery connector | ||
1 | 1 MoPi power board | ||
1 | 2A micro USB power cable |
Assembly instructions:
- Remove the lens from the Raspberry Pi camera. Using a pair of pliers (the kind with a ridged surface), grip the top circular plastic part of the lens and rotate counter-clockwise. We find it\'s easiest to grip the lens firmly and rotate the sensor, rather than the other way around.
- Using super glue (we recommend Loctite\; apply with a brush) glue the following parts\:
- nuts (x3) on the bottom of the stage
- legs (x1 large + x2 small)
- screw caps (x3)
- the 2 parts of the z axis together
- RPi lens into lens holder
- supporting axes (x2) into cube holder
- washer into large leg (around the hole) '
if(options[5] == 0) {
ret += ' - screw holders (x3) '
} if(options[5] == 1) {ret += '
} if(options[5] == 2) {ret += '
}ret += '' return $('
').html(ret)
}
step0.bind(step1, [1]);
step1.bind(step2, [0]); step1.bind(step2, [1]);
step2.bind(step3, [0]); step2.bind(step3, [1]);
step3.bind(step4, [0]); step3.bind(step4, [1]);
step4.bind(step5, [0]); step4.bind(step5, [1]);
step5.bind(step6, [0]); step5.bind(step6, [1]); step5.bind(step6, [2]);
step6.bind(final, [0]); step6.bind(final, [1]); q.start(step0);});