Autor:	Onyesi John Abiagam
Sprache:	DE EN

Introduction

The Ambient Light Sensor (VEML7700) is a high-accuracy sensor with 16-bit resolution. It integrates a highly sensitive photodiode, a low-noise amplifier, and a built-in analog-to-digital converter to enable precise light measurements. The sensor communicates via a simple I²C interface and provides ambient light data directly in digital form.

Technical Overview

Key Features

Feature	Description
Package Type	Surface-mount (SMD), side-view
Dimensions	6.8 mm × 2.35 mm × 3.0 mm
Sensor Type	Ambient Light Sensor (ALS)
Resolution	16-bit digital output
Supply Voltage (VDD)	2.5 V to 3.6 V
Communication Interface	I²C
Dynamic Range	0 lx to about 140 klx
Sensitivity	Up to 0.0042 lx/count
Flicker Rejection	100 Hz and 120 Hz noise suppression
Power Consumption	Low shutdown current ( about 0.5 µA typical)
Temperature Stability	Built-in temperature compensation
Additional Feature	Software-controlled shutdown mode

Components Requirements

Component	Description
Arduino Uno	Microcontroller board used to interface with the sensor
VEML7700 Sensor Module	Ambient light sensor with built-in I²C support and onboard circuitry
Jumper Wires	Used to connect the sensor module to the Arduino

Pin Configuration

Pin Number	Pin Name	Description
1	SCL	Serial Clock Line for I²C communication
2	VDD	Power supply (2.5 V – 3.6 V)
3	GND	Ground
4	SDA	Serial Data Line for I²C communication

Measurement Method

Reference Lux Meter Reading vs LX-1108 Measurement

• Measurements were obtained simultaneously using the laboratory reference lux meter and the LX-1108 lux meter.
• The laboratory reference lux meter served as the reference instrument, while the LX-1108 was treated as the instrument under investigation.
• The relationship between the two instruments was examined over the selected light range.
• Table 1 presents the recorded measurements obtained from both instruments.
• Figure 1 shows the corresponding LX-1108 measurements plotted against the reference lux meter readings.
• The observed deviation between the two instruments suggests that the relationship cannot be adequately represented by a single constant correction factor.

Note: The analysis presented here is specific to Lab Reference lux meter and LX-1108 lux meter.

Table 1: Reference Lux Meter and LX-1108 Measurement Data

Table 1: Reference Lux Meter and LX-1108 Measurement Data

Reference Lux Meter (Lab_Ref) [Lux]	LX-1108 Reading (LX_Reading) [Lux]
0	0
64	51
1174	924
2349	1889
3226	2573
4091	3247
5049	3870
6307	4880
7070	5570
8231	6510
9105	7150
10340	7990
11213	8780
12361	9670
13259	10030
14058	10450
15334	11200
16257	11700
17322	12500
18078	13400
19737	14600

Figure 1 illustrates the relationship between the laboratory reference lux meter readings and the corresponding LX-1108 measurements.

• The LX-1108 readings generally increased with increasing reference illuminance.
• The relationship between the two instruments was not perfectly proportional across the measurement range.
• The varying deviation suggests that a nonlinear model is required to accurately characterize the relationship.
• Consequently, nonlinear regression was employed to establish a calibration model for the LX-1108.

Relative Error Before Calibration

To quantify the deviation between the laboratory reference lux meter and the LX-1108, the relative error was calculated as:

$$\begin{gathered} {\displaystyle Relative \\ Error=\frac{LabRef-LXReading}{LabRef}\times 100} \end{gathered}$$

where LabRef represents the laboratory reference lux meter reading and LXReading represents the corresponding LX-1108 measurement.

• The LX-1108 showed a deviation relative to the laboratory reference lux meter.
• The error was not constant and generally increased at higher illuminance levels.
• The varying error indicates that a single constant scaling factor would not adequately compensate for the observed deviation.
• Therefore, a nonlinear regression model was developed to characterize the relationship between the laboratory reference lux meter and the LX-1108.

The nonlinear regression procedure and the resulting calibration model are presented in the following section.

Nonlinear Regression

The results presented in Figure 1 and Figure 2 indicate that the LX-1108 exhibits a systematic and non-uniform deviation relative to the laboratory reference lux meter. Furthermore, the relative error varies across the measurement range, suggesting that the relationship between the two instruments cannot be adequately described using a single constant scaling factor.

To mathematically characterize this relationship, a nonlinear regression model was developed using the experimental measurement data. The laboratory reference lux meter readings (LabRef) were treated as the independent variable, while the corresponding LX-1108 measurements (LX_Reading) were treated as the dependent variable.

A power-law regression model was selected and expressed as:

${\displaystyle LXReading=a(LabRef{)}^b}$

where:

• ${\displaystyle a}$ is the scaling coefficient,
• ${\displaystyle b}$ is the nonlinear exponent,
• ${\displaystyle LabRef}$ represents the laboratory reference lux meter reading, and
• ${\displaystyle LXReading}$ represents the corresponding LX-1108 measurement.

The model parameters were estimated using MATLAB's nonlinear regression fitting tools to obtain the best representation of the observed relationship between the laboratory reference lux meter and the LX-1108.

Regression Results

The nonlinear regression procedure produced the following parameter estimates:

• Scaling coefficient: ${\displaystyle a=1.428934}$
• Nonlinearity exponent: ${\displaystyle b=0.932233}$

Substituting these values into the regression model yields:

${\displaystyle LXReading=1.428934(LabRef{)}^{0.932233}}$

• The blue markers represent the experimental measurements obtained from the LX-1108 and the laboratory reference lux meter.
• The red curve represents the fitted nonlinear regression model.
• The dashed black line represents the ideal relationship (${\displaystyle y=x}$) between the two instruments.
• The fitted model captures the deviation of the LX-1108 relative to the laboratory reference lux meter.
• The resulting regression equation provides the mathematical basis for deriving a calibration function for the LX-1108.

Derivation of the TrueLux Function

Using the nonlinear regression model derived in the previous section, an inverse function was established to estimate the corresponding reference luxmeter value from a measured LX-1108 reading.

The resulting inverse relationship is:

${\displaystyle TrueLux={\left(\frac{MeasuredLux}{1.428934}\right)}^{\frac{1}{0.932233}}}$

Defining this inverse relationship as:

${\displaystyle Lux2Ref(MeasuredLux)}$

the function can be expressed as:

${\displaystyle TrueLux=Lux2Ref(MeasuredLux)}$

where:

• ${\displaystyle MeasuredLux}$ is the measured LX-1108 reading.
• ${\displaystyle Lux2Ref()}$ is the calibration function derived from the nonlinear regression model.
• ${\displaystyle TrueLux}$ is the estimated reference lux value.

Calibration of LX-1108 Measurements

The nonlinear regression model was used to establish a calibration function capable of estimating the corresponding reference lux value from a measured LX-1108 reading.

The calibration function was subsequently applied to the LX-1108 measurements to obtain corrected Lux values.

• The corrected measurements closely follow the ideal relationship (${\displaystyle y=x}$).
• The systematic deviation observed in the raw LX-1108 measurements has been substantially reduced.
• The corrected values exhibit improved agreement with the laboratory reference lux meter readings.
• The results demonstrate the effectiveness of the calibration function in estimating the corresponding reference values.

Relative Error After Calibration

The relative error after calibration was calculated using:

$$\begin{gathered} {\displaystyle Relative \\ Error=\frac{LabRef-CorrectedLux}{LabRef}\times 100} \end{gathered}$$

where:

• ${\displaystyle LabRef}$ represents the laboratory reference lux meter reading.
• ${\displaystyle CorrectedLux}$ represents the calibrated LX-1108 measurement.

• The relative error was significantly reduced after calibration.
• The remaining error is considerably smaller than that observed before calibration.
• The calibrated LX-1108 measurements show improved relationship with the laboratory reference lux meter.

Important Limitation:

• The function ${\displaystyle TrueLux=Lux2Ref(MeasuredLux)}$ was derived exclusively from calibration data obtained using the LX-1108 lux meter and the laboratory reference lux meter.
• The function is intended only for estimating reference-equivalent values from LX-1108 measurements.
• The function was not derived using VEML7700 measurement data.
• Consequently, the function cannot be assumed to provide accurate reference illuminance estimates for the VEML7700 sensor.
• Since the VEML7700 exhibits different sensing characteristics and measurement behaviour, an independent calibration procedure is required to establish a corresponding calibration function.

VEML7700 Automatic Gain and Integration Time Selection Across Varying Light Levels

The VEML7700 measurements were obtained using the Adafruit VEML7700 library. The library provides an auto-ranging feature that automatically adjusts the sensor gain and integration time according to the measured light level. This allows the sensor to operate over a wide range of lighting conditions without requiring manual configuration of these parameters.

To observe the behavior of the auto-ranging feature, measurements were taken in the Light Laboratory using a LabRef luxmeter as the reference instrument. For each light level, the corresponding VEML7700 reading and the automatically selected gain and integration time settings were recorded. The results are summarized in Table 2.

Table 2.This Shows the Automatic Selection and Adjustment of Gain and Integration Time Across Different Reference light Levels Measured Using the LabRef Luxmeter and VEML7700 Sensor

Reference Luxmeter Value	Raw ALS Count	Lux	Auto Gain and Integration Time Selection
0	0	0	Gain = 2, IT = 800 ms
588	1079	517.87	Gain = 1/8, IT = 100 ms
1283	2231	1107	Gain = 1/8, IT = 100 ms
1993	3522	1804.77	Gain = 1/8, IT = 100 ms
2727	4723	2483.48	Gain = 1/8, IT = 100 ms
3447	5854	3143.58	Gain = 1/8, IT = 100 ms
4158	6937	3793.18	Gain = 1/8, IT = 100 ms
4862	7974	4426.77	Gain = 1/8, IT = 100 ms
5561	8967	5046.89	Gain = 1/8, IT = 100 ms
6255	9914	5650.44	Gain = 1/8, IT = 100 ms
6943	5414	6239.62	Gain = 1/8, IT = 50 ms
7627	5855	6816.50	Gain = 1/8, IT = 50 ms
8305	6283	7388.46	Gain = 1/8, IT = 50 ms
8977	6691	7996.35	Gain = 1/8, IT = 50 ms
9646	7085	8495.75	Gain = 1/8, IT = 50 ms
10310	7466	9039.77	Gain = 1/8, IT = 50 ms
10968	7833	9581.76	Gain = 1/8, IT = 50 ms
11622	8188	10116.07	Gain = 1/8, IT = 50 ms
12270	8526	10694.13	Gain = 1/8, IT = 50 ms
12914	8860	11181.97	Gain = 1/8, IT = 50 ms
13554	9182	11708.92	Gain = 1/8, IT = 50 ms
14189	9495	12241.26	Gain = 1/8, IT = 50 ms
14820	9796	12774.04	Gain = 1/8, IT = 50 ms
15445	5045	13307.01	Gain = 1/8, IT = 25 ms
16065	5187	13847.48	Gain = 1/8, IT = 25 ms
16680	5324	14383.75	Gain = 1/8, IT = 25 ms
17290	5459	14931.21	Gain = 1/8, IT = 25 ms
17898	5593	15494.61	Gain = 1/8, IT = 25 ms
18500	5720	16039.33	Gain = 1/8, IT = 25 ms
19061	5835	16566.99	Gain = 1/8, IT = 25 ms
19490	5922	16975.82	Gain = 1/8, IT = 25 ms
19655	5956	17136.62	Gain = 1/8, IT = 25 ms
19682	5961	17160.41	Gain = 1/8, IT = 25 ms

VEML7700 Automatic Gain and Integration Time Adjustment Procedure (Vishay Datasheet)

According to Vishay, the VEML7700 auto-ranging algorithm automatically adjusts the gain and integration time to keep the ALS count within a suitable measurement range. The process can be summarized as follows:

• Start with the lowest gain setting (gain × 1/8) and an integration time of 100 ms.
• Measure the ALS count.
• If the ALS count is less than or equal to 100 counts, increase the gain from × 1/8 to × 1/4.
• If the ALS count is still less than or equal to 100 counts, increase the gain to × 1.
• If the ALS count is still less than or equal to 100 counts, increase the gain to × 2.
• If the ALS count remains less than or equal to 100 counts at the highest gain setting, increase the integration time from 100 ms to 200 ms, and continue increasing it up to a maximum of 800 ms if required.
• For high light levels, reduce the sensor sensitivity by decreasing the gain or integration time to prevent ALS count saturation.
• Once the ALS count falls within the recommended operating range, calculate the lux value using the corresponding resolution factor.
• Apply the correction formula for high light levels when required to compensate for sensor non-linearity.

A detailed flowchart of the complete auto-ranging procedure is provided in the Vishay application note datasheet( see link at the end of the page).

Measurement Circuit

Software

Arduino IDE

Simulink

Video

Datasheets

• VEML7700 Datasheet

• Designing the VEML7700 Into an Application (Application Note)

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