Difference between revisions of "Resistance meter"
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==Objective== | ==Objective== | ||
| − | The course will show you how to use Processing to display the | + | The course will show you how to use Processing software to display the value of the resistance meter in the form of the graph, and the resistance meter can be achieved by Microduino. |
==Equipment== | ==Equipment== | ||
| Line 33: | Line 33: | ||
==Debugging== | ==Debugging== | ||
| − | Step | + | Step 1:Building hardware environment according to the schematic diagram, just as follows: |
[[File:IResistanceMeterConnectionDiagram.jpg|600px|center|thumb]] | [[File:IResistanceMeterConnectionDiagram.jpg|600px|center|thumb]] | ||
| − | Step | + | Step 2: Here is the code we need: |
The code of two ends (Processing and Microduino) | The code of two ends (Processing and Microduino) | ||
| Line 66: | Line 66: | ||
myPort.bufferUntil('\n'); // Trigger a SerialEvent on new line | myPort.bufferUntil('\n'); // Trigger a SerialEvent on new line | ||
| − | //On the | + | //On the screen, displaying the data received from Microduino in the form of graph and marking scale. |
String val = myPort.readStringUntil('\n'); | String val = myPort.readStringUntil('\n'); | ||
| Line 97: | Line 97: | ||
text ( resistance+unit, 0, 10); | text ( resistance+unit, 0, 10); | ||
| − | Step | + | Step 3: Download the code and get it compiled successfully. |
| − | Step | + | Step 4: Putting the resistor ready to measure between the yellow and the black lines on the graph, watching resistance on Processing. |
==Result== | ==Result== | ||
Latest revision as of 09:18, 13 September 2016
ObjectiveThe course will show you how to use Processing software to display the value of the resistance meter in the form of the graph, and the resistance meter can be achieved by Microduino. Equipment
Schematic Diagram
ProgramReferring to ResistanceMeter processingResistanceMeter DebuggingStep 1:Building hardware environment according to the schematic diagram, just as follows:
The code of two ends (Processing and Microduino) Microduino: //Using filter algorithm to calculate resistance and displaying the data on Processing via serial output. //filter Algorithm
float filter()
{
float sum = 0;
for(int count = 0; count < N; count++)
{
sum += r;
delay(5);
}
return (float)(sum / N);
}
Processing: //After getting the data of the first serial port, you can define or cache the data if there is a new line. // is always my Microduino, so I open Serial.list()[0].
// Open whatever port is the one you're using.
myPort = new Serial(this, Serial.list()[0], 9600);
myPort.bufferUntil('\n'); // Trigger a SerialEvent on new line
//On the screen, displaying the data received from Microduino in the form of graph and marking scale. String val = myPort.readStringUntil('\n');
if (val != null) {
if ("Infinity!!".equals(val)) {
unit="resistancetoo big";
}
else {
if ("K ohm".equals(val)) {
unit="K ohm";
}
else if (" ohm".equals(val)) {
unit=" ohm";
}
else {
val = trim(val);
println(val);
resistance=Float.parseFloat(val);
}
}
}
vals[vals.length-1] = 200-resistance;
//Display scale
text ( "200-", 370, 10);
text ( "--", 370, 50);
text ( "100-", 370, 100);
text ( "--", 370, 150);
text ( "0-", 370, 200);
//show current num
text ( resistance+unit, 0, 10);
Step 3: Download the code and get it compiled successfully. Step 4: Putting the resistor ready to measure between the yellow and the black lines on the graph, watching resistance on Processing. ResultThe graph will display the current resistance.
Video |
