After interfacing the TMP102 temperature sensor recently with the Bus Pirate, the next step on my agenda was to integrate this with the Web Platform along with a HH10D humidity sensor. Unfortunately I realised a bit late (entirely my fault rushing an order) that although the HH10D was an I2C sensor, the humidity was actually read through a frequency output pin; the I2C EEPROM was only for calibration data. Bus Pirate to the rescue once again!
This, like the TMP102 is an 3.3V sensor and needs pullup resistors on the I2C bus to read the EEPROM. I
wasted spent a number of hours with this getting nothing but garbage data with the first sensor I tried (the calibration values were completely wrong), on the second try with a backup sensor I had much better luck, getting good results almost immediately.
We’ll be doing a similar setup to the TMP102: using I2C and turning on the power supplies but in this case the AUX pin should be set to HIGH-Z for input/reading.
HiZ> m 1. HiZ 2. 1-WIRE 3. UART 4. I2C 5. SPI 6. 2WIRE 7. 3WIRE 8. KEYB 9. LCD x. exit(without change) (1)> 4 Set speed: 1. ~5KHz 2. ~50KHz 3. ~100KHz 4. ~400KHz (1)> 3 Ready I2C> c a/A/@ controls AUX pin I2C> @ AUX INPUT/HI-Z, READ: 0 I2C> W Power supplies ON I2C> (1) Searching I2C address space. Found devices at: 0xA2(0x51 W) 0xA3(0x51 R)
Good. Now if you take a look at the datasheet for the M24C02 EEPROM to do a random address read you’ll need to send a start bit, device select (read only; R/W set to 0), address, then another start bit, device select again (but with R/W set to 1), then read commands. The HH10D datasheet mentions there are 2 calibration factors we need to read: sensitivity and offset and each are 2 byte integers, making a total of 4 bytes. These start at address EEPROM address 10. Using the BP, we do the following:
I2C> [0xa2 0x0a [0xa3 r:4 I2C START BIT WRITE: 0xA2 ACK WRITE: 0x0A ACK I2C START BIT WRITE: 0xA3 ACK READ: 0x01 ACK 0x8B ACK 0x1E ACK 0x32 I2C>
This is in big-endian format so the sensitivity value (at address 0x10) reads 0x018B and the offset is 0x1E32. We’ll also do a frequency read, the first as baseline with my AC running nearby and the second breathing on the sensor:
I2C> f AUX Frequency: autorange 7,169 Hz I2C> f AUX Frequency: autorange 6,790 Hz
The formula in the datasheet states the RH = (offset-freq) * sensitivity/4096. Plugging these in we get 54% and 90.6% RH which seems to match the other humidity sensor in my room. Success!
Next step was getting this working on my Web Platform. I have some very bare-bones code working with the TMP102 already, just need to work on the HH10D a bit more and I’ll post my example up here.