# Meaning of “LSB/Unit” and “Unit/LSB”

At the moment I'm playing with the LSM303DLHC accelerometer/magnetometer/thermometer.

Everything is working quite well, but I don't know how to interpret the output values. The datasheet (page 9) says something like "1 mg/LSB" (no, it's not milligramm :D) about the linear acceleration sensitivity in my configuration. What the hell should that mean? Same with temperature sensor output change (8 LSB/°C) and magnetic gain setting (1100 LSB/gauss), only the other way around.

For example, what to do with this accelerometer output: 16384? That is my measured gravitational acceleration.

• A guess: mg is millli g where g is acceleration due to gravity, and LSB is least significant bit. So adding 1000 the readout out should mean adding 1 G of acceleration. The fact that your reading is 16 G's should probably worry you (grin). – Dale Wilson Oct 3 '13 at 14:35
• That would mean the precision of the temperature readings is 0.125C which seems plausible. – Dale Wilson Oct 3 '13 at 14:37
• The fact with the physical units was clear. I'm confused about the term "LSB" in this context. From your explanation I conclude that it means an increase or decrease of the output by 1. To calculate the accelerometer's output I just have to multiply it with 1 mg? And for the megnetometer's output i have to divide the value by 1100 Gauss? – Genesis Rock Oct 3 '13 at 14:46
• The fact that 16384 is 0x4000 worries me. That does not look like a valid reading. – Dale Wilson Oct 3 '13 at 15:14
• NOTE: I think you are reading big endian values or something. The accelerometer registers are little endian by default (there's a control register to switch it) and the data is signed integers (2's compliment). – Eric Jan 18 '15 at 3:17

LSB/unit or Unit/LSB is the factor(called sensitivity) with which you have to multiply the raw sensor data. Say Sensor A has X,Y and Z registers , the values coming in each of the registers needs to be Divided/multiplied with the LSB/unit or Unit/LSB factor. This is because the data sheet says @ the particular fullscale you will have this much sensitivity(LSB/unit or Unit/LSB)

for LSB/Unit :

x lsb means - 1 unit

1 lsb means - 1/x unit

value lsb(value in the register) = (1/x)*(value in the register) - Apply unitary method here.

similarly for Unit/LSB you have to multiply the sensitivity.

You can build Accelerometer,Magnetometer or Temperature sensor or may be Gyro-meter in one module, but what if a customer/User wants only one sensor?

Rgds, Rp

Now I got the trick. There are several things on this MEMS you have to know, but which are not mentioned in the datasheet:

1. The accelerometer's output register is just 12 bits and not 16 bits, so you need to right-shift the value by 4 and multiply it with 0,001 G. Furthermore it's little-endian.
2. The magnetometer's output register is 16 bits, but big-endian. Furthermore the vector order is (X|Z|Y) not (X|Y|Z). To calculate the correct value you need to devide X and Y by 980 gauss⁻¹, while it's 1100 gauss⁻¹ for Z.
3. The temperature sensor works, but it's not calibrated. So you can use it to measure temperature change, but no absolute temperatures. It's also just 12 bits, but big-endian and you have to devide the output by 8 C⁻¹.

With that Information it's possible to use the LSM303DLHC. But who the hell invented this? "Let's build a new accelerometer, magnetometer and thermometer in one package and screw the user up by mixing word length and endianness up without mentioning it in the datasheet."

• All these things are common, have their reasons, and are mentioned in the data sheet (at least the couple I checked). That's what I meant in my comment above that it's very easy to misinterpret the registers: you can't make reasonable guesses at what's in the datasheet, but need to read it. – tom10 Oct 3 '13 at 19:49
• Okay, show me where it says that the accelerometer output is only 12 bit. I couldn't find it. In contrast, the datasheet promotes the device with "16 bit data output". – Genesis Rock Oct 4 '13 at 20:30
• That's ridiculous. You said things weren't in there and they were, so now you say, "but 12 bits really, really isn't in there." Honestly, I can't believe I bothered to look the first time. – tom10 Oct 4 '13 at 23:35
• Up vote for concluding remarks – Jimi Jan 29 '15 at 19:50
• Genesis Rock is correct. 12 bit resolution or left justification of the accelerometer data is not mentioned in the datasheet. ST dropped the ball on that in a significant way. Something like that should really be prominently shown. This isn't a misinterpretation of the registers - the information required to interpret them just isn't there! This answer helped me also. Thanks! – Dan Puccio Mar 27 '15 at 19:31

The datasheet is definitively unclear regarding the interpretation of the Acceleration registers. Genesis Rock solution assume it is 12-bits, which works. (Another solution is to assume gain is 16 mg/LSB instead of 1 mg/LSB, but as the last 4 bits of the accelerations seem to always be zeros the former solution makes more sense).

But both for the temperature and acceleration, if you take into account only the 12 most significant bits. The last two bits are still also always zero, so the effective resolution would be 10-bits which is confusing.

I also can't make sense of the temperature reading unless there is an unknown offset not specified in the datasheet.

I hope others can confirm they are getting the same results.

Regarding the 12 bit output of the accelerometer: there is a high-resolution flag on control register 4. It's off by default and there's no information on what high resolution means. I'm guessing that it might enable 16 bit output. Also on control register 4 is a flag to set the endianness of the accelerometer output. It's little endian by default. The data sheet is pretty weak overall.