GY-63_MS5611/libraries/BH1750FVI_RT
2021-05-28 14:16:25 +02:00
..
.github/workflows add arduino-lint 2021-05-28 13:17:38 +02:00
examples 2021-01-29 2021-01-29 12:31:58 +01:00
test 2021-01-29 2021-01-29 12:31:58 +01:00
.arduino-ci.yml 2021-01-29 2021-01-29 12:31:58 +01:00
BH1750FVI.cpp 2021-01-29 2021-01-29 12:31:58 +01:00
BH1750FVI.h 2021-01-29 2021-01-29 12:31:58 +01:00
keywords.txt 2021-01-29 2021-01-29 12:31:58 +01:00
library.json add license to library,json 2021-05-28 14:16:25 +02:00
library.properties 2021-01-29 2021-01-29 12:31:58 +01:00
LICENSE 2021-01-29 2021-01-29 12:31:58 +01:00
README.md 2021-01-29 2021-01-29 12:31:58 +01:00

Arduino CI License: MIT GitHub release

BH1750FVI_RT

Arduino library for BH1750FVI (GY-30) 16 bit I2C Lux sensor

Description

The BH1750FVI is a 16 bit lux sensor with an I2C interface It is possible to detect a wide range from 0.11 - 100000 lux.

To be able to support this wide range, the sensor can operate in three modi.

ID Mode Integration time Resolution Notes
0 LOW 16 ms 4.0 Lux to measure very bright light
1 HIGH 120 ms 1.0 lux default
2 HIGH2 120 ms 0.5 lux to measure very dim light

Furthermore one can set a correction factor to reduce / increase the integration time of the sensor. The factor should be between 0.45 - 3.68. It can be used to increase the working range like very bright or very low light conditions. Another aplication is to correct the transparancy of material, or the type of light used.

Note that the typical integration time will differ if the correction factor is changed. The isReady() an getLux() functions keep track of the adjustment needed.

Interface hardware

Library was tested with a breakout board.

//  breakout BH1750FVI / GY-30
//
//      +-----------------------+
//  GND |o                      |
//  ADD |o                      |
//  SDA |o            +         |  + = sensor
//  SCL |o                      |
//  VCC |o                      |
//      +-----------------------+
//
// ADD = ADDRESS:
//   0 = 0x23
//   1 = 0x5C
//

The sensor works on 2.4 - 3.6 volt so be careful not to connect directly to 5.0 volt. (Note: the breakout board was 5 volt tolerant)

Interface

Constructor

  • BH1750FVI(address, dataPin, clockPin) ESP constructor with I2C parameters
  • BH1750FVI(address, TwoWire *wire = &Wire) constructor for other platforms
  • begin() resets some internal vars to default. Use with care.

Base

  • getRaw() reads the lux sensor,
  • getLux() reads the lux sensor and corrects for correctionFactor and for HIGH2 mode,

management

  • getError() get the latest error, mainly for debugging,
  • powerOn() wakes up the sensor,
  • powerOff() set sensor to sleep,
  • reset() resets the dataregister to 0, effectively removing last measurement.

Mode operators

  • getMode() gets the mode set by one of the set functions. See table above.
  • setContHighRes() continuous mode in HIGH resolution
  • setContHigh2Res() continuous mode in HIGH2 resolution
  • setContLowRes() continuous mode in LOW resolution
  • setOnceHighRes() single shot mode in HIGH resolution
  • setOnceHigh2Res() single shot mode in HIGH2 resolution
  • setOnceLowRes() single shot mode in LOW resolution

CorrectionFactor

Please read datasheet P11 about details of the correction factor.

  • isReady() can be used to check if the sensor is ready. This is based on a calculated time, the sensor does not have a means to indicate ready directly. Needed only for the single shot modi. The function isReady() takes the correctionfactor into account.
  • changeTiming(uint8_t val) 69 is default = BH1750FVI_REFERENCE_TIME
  • setCorrectionFactor(float f) prefered wrapper around changeTiming f = 0.45 .. 3.68
  • getCorrectionFactor() returns the correction factor. Note this can differ as it is stores as an integer internally.

Angle sensitivity

Note: experimental - use carefully

The lux sensor is really sensitive for the angle of the light. If one makes measurements outside, the position of the sun changes during the day. The setAngle(degrees) function provides a mean to correct that.

The angle adjustments is based upon the figure 4 and 5 (directional characteristics.) which describe Lamberts Cosine Law. (details see wikipedia) So the correction factor is factor = 1.0 / cos(angle). At 90 degrees it would fail (divide by zero) so the input is constrained to angles between -89 - +89 degrees.

If the light is perpendicular on the sensor the angle to use is 0 degrees. Light coming from the side is 90 degrees.

  • setAngle(int degrees) adjust the lux to incoming angle in dgrees
  • getAngle() returns set angle in degrees, 0 by default is perpendicular

Temperature Compensation

The reference temperature of the sensor = 20°C. The effect of temperature is small, about 3% per 60°C ==> 1% per 20°C so only on either a hot roof or on a icy cold day the effect is measurable.

  • setTemperature(int T) see datasheet P3 fig7
  • getTemperature() returns temperature set, default = 20°C

Spectral Compensation ! EXPERIMENTAL !

Spectral compensation is experimental and not tested. It is a compensation based upon the graph figure 1, page 3 of the datasheet. If one has light of a known wavelength one can compensate for it by setting the wavelength. It can also be used when using filters. As said it is not tested so use at your own risk, but I am interested in your experiences if you do real tests with it.

  • void setSpectral(int wavelength) set wavelength,
  • int getSpectral() returns wavelength

As the graph (figure 1) is not lineair it is approximated by linear interpolation with the following six points.

WaveLength Perc %
400 1
440 10
510 90
545 80
580 100
700 07
725 1

Values outside the range will be mapped upon 400 or 715. Default wavelength will be 580 as that gives 100%

Ideas

  • Intelligent isReady() After a getLux() call one can clean the dataregister explicitly with reset(). Then a call to isReady() fetches data and as long as data equals zero the sensor is not ready.

  • DVI interface To investigate, sort of external reset?

Operation

See samples...