# how to get Celsius as output from LM335Z with arduino?

the firstsensor is my lm335z output.

``````int firstSensor = 0;
int secondSensor = 0;
int thirdSensor = 0;
int inByte = 0;

void setup()
{
Serial.begin(9600);
establishContact();  // send a byte to establish contact until receiver responds
}

void loop()
{
if (Serial.available() > 0) {
delay(10);
Serial.print(firstSensor, DEC);
Serial.print(",");
Serial.print(secondSensor, DEC);
Serial.print(",");
Serial.println(thirdSensor, DEC);
}
}

void establishContact() {

}
``````
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Based on its datasheet, the temperature output will vary at 10mV/K. But if you find a reference voltage at a known reference temperature, you can use this helpful equation from the datasheet:

`V_out = V_ref * T_out/T_ref` which is equivalent to `T_out = T_ref * (V_out/V_ref)`

So say your voltage is 2.982V at 25 degrees C or 298.15 degrees Kelvin (this is suggested in datasheet), then you can set your equation to:

`T_out = (298.15 Kelvin)(V_out/2.982V)-273.15`

So assuming you already can convert an analog reading into a voltage*, just plug in the measured voltage and this should give you your temp in degrees C.

*The Arduino has a built-in 10-bit ADC and the maximum voltage it can read is 5v. Therefore, you can factor in 5v/1024 ADC steps = 0.00488V per ADC step. (i.e. `V_out = firstSensor*0.00488`). So plugging in for V_out, the equation becomes:

`T_out = (298.15)(firstSensor*0.001637)-273.15` where 0.001637 = 0.00488/2.982.

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Never multiply by a small floating point constant to get a value -- floating point is imprecise and often people don't enter enough digits in the constant to be precise -- 5 / 1024 = 0.048828125. Likewise, be very careful with A/DC conversions as the range is not as you calculated. An A/DC value of 1023 from an ATmega328 (uMC for the Arduino) is equal to Vcc (supply voltage) -- not 1024. That is, analogRead(A0) returns 1023 when the A0 pin equals Vcc. You'll be off by 4.88mv (or more -- see previous) if you use 0.00488 as the value. To check: 1023 * 0.00488 = 4.99224, or 1*K too low. – Julie in Austin Apr 15 '12 at 9:42