ams AS7341 Sensor Chip User Guide

ams AS7341 Sensor Chip

Product Information

Introduction

This application note provides important optical and mechanical parameters that need to be considered when designing the AS7341 into an application- specific sensor system.

AS7341 Sensor Chip

The AS7341 is an optical multi-channel sensor with eight spectral channels in the visible light range (VIS), a NIR channel, and an open channel for flicker detection. The VIS channels are arranged in a 4 x 4 matrix with two photodiodes per channel. The NIR and flicker channels have one big photodiode each, placed next to the matrix.

The AS7341 integrates interference filters into standard CMOS via nano-optic deposited interference filter technology. These filters are stable over a lifetime without any drifts. They are designed as spectral filters with an even arrangement over VIS and one filter in NIR.

The optical filter characteristics, such as irradiance responsivity, center wavelength, and FHWM, are listed in the AS7341 datasheet [1]. Please take note of the minimum and maximum values specified based on the series deviations.

The responsivities of the spectral channels were defined under specific conditions. Therefore, the measured values may deviate from these values under changed conditions. The same applies to the electronic amplifier/converter results (excluding the AutoZero function on the chip) and temperature dependencies. We recommend investigating and correcting such variations in the overall system. For more details, please refer to the datasheet [1].

AS7341 Sensor Chip Dimensions

The AS7341 is available in an ultra-low profile package with dimensions 3.1 mm x 2.0 mm x 1.0 mm. For more details on the dimensions and position of the photodiodes, please see Figure 4 and Figure 5.

Introduction

• This application note describes the most important optical and mechanical parameters that are needed to be considered when designing the AS7341 into an application-specific sensor system.

AS7341 Sensor Chip

The AS7341 is an optical multi-channel sensor with eight spectral channels in the visible light range (VIS), a NIR channel, and an open channel for flicker detection. The VIS channels are arranged in a 4 x 4 matrix with two photodiodes per channel. The NIR and flicker channels have one big photodiode, each placed next to the matrix.

The AS7341 integrates interference filters into standard CMOS via nano-optic deposited interference filter technology. These filters are stable over a lifetime without any drifts. They are designed as spectral filters with an even arrangement over VIS and one filter in NIR. The optical filter characteristics, such as irradiance responsivity, center wavelength, and FHWM are listed in the AS7341 datasheet [1]. Please take a note of the minimum and maximum values that are specified, based on the series deviations. The data for responsivities of the spectral channels were defined under specific conditions Therefore, the measured values may deviate from these values under changed conditions.

The same applies to the electronic amplifier/converter results (exclude the AutoZero function on the chip) and temperature dependencies. We recommend that such variations should be investigated and corrected in the overall system. For more details, please check the datasheet [1].

• The device is available in an ultra-low profile package with the dimensions 3.1 mm x 2.0 mm x 1.0 mm.
• For more details on the dimensions and position of the photodiodes, please see Figure 4 and Figure 5.

Optical Diffuser Requirements

• The photodiodes within the AS7341 have a near-cosine response to incoming light. Color filters used for the channel separation are specifically designed interference filter stacks on top of the photodiodes. Due to physical effects in the filter stacks, the interference filters are only designed for a limited range of the angle of incidence (AOI) and expect a Lambertian power distribution.
• The maximum angle of incidence to the photodiodes is limited to the design requirements of the filter stack by the aperture/pinhole of the package. The rays with the most obtuse angle hit the edges of the photodiodes from the opposite edge of the aperture (Figure 6).
• To meet the requirements of power distribution, it is necessary to use an achromatic diffuser that emits light with a Lambertian characteristic to the sensor independent of the angle of incidence. The minimum scatter characteristic is shown in Figure 7. If the diffuser is placed very close to or directly on the AS7341 package, its structure has to be very fine to get the same distribution to each photodiode of the detector array.
• It is also important to note that the technical parameters listed in the datasheet [1] apply to a diffuser in front of the sensor. Different diffusers, and the use without a diffuser, lead to different sensor parameters.
• A recommended diffuser is pre-mounted on the AS7341 evaluation kit, directly above the sensor using two simple plastic shells as a diffuser holder and adapter, which are fixed on the evaluation kits by two bolts and nuts. During the new installation of the diffuser holder, ensure that the diffuser is correctly placed between the upper and lower plastic holder. Fix the bolts and nuts by hand and check that all are fixed. Ensure not to touch the optical diffuser with your fingers.
  • Figure 9: Diffuser Parameters
    Parameter| Value
    ---|---
    Diffuser material| Kimoto 100 PBU
    Diffuser thickness| 125 microns
    Transmission| 66%
    Haze| 89.5%
    Half-angle| 35.5°
• Please note that the diffuser specification depends on the customer application and planned position in front of the sensor. Therefore, check the technical parameters of the standard diffuser (see Figure 9 for the technical details) before starting any tests. Select a diffuser with sufficient diffusing power such that the sensor has a smooth angular response (no spikes in the angular response curves) exceeding ±45° (FHWM). Limited tests of the diffuser can be made using the AS7341 EVKs.
• The diffuser in the EVK can be changed quickly and easily. Ensure not to touch the diffusers with your fingers during any mounting activities. The surface of the diffusers is very sensitive, and any touch, mechanical stress, or dirt can dramatically change the optical behavior. Changing and reassembling the diffuser typically changes the calibration parameters and requires recalibration for optimal results.
• Figure 9 lists the recommended diffuser parameters and/or the parameters of the Kimoto diffuser used in the AS7341 EVK.

Diffuser Types and Recommendations for Selection

For application in front of the AS7341, a translucent diffuser is required, which uses scattering centers to spread incoming directed light in pseudorandom directions. These scattering centers can be tiny surface structures on the top (e.g. grounded glass) or small white particles inside (e.g. opal glass) the diffuser. This property can be used to divide diffusers into two main groups: surface diffusers and volume diffusers.

Surface Diffusers

Surface diffusers usually consist of a clear base material, which is structured on one or both plane surfaces. The structures are microscopically small and random to refract incoming light depending on the orientation of every single ray towards the surface segment where it hits the diffuser. According to Snell’s law, the level of refraction also depends on the wavelength, which could cause chromatic aberrations in the border regions. Scattering is often enhanced by structuring the input and output surface of the diffuser, which leads to multiple refractions and partly to internal reflections. Due to refraction as the main effect, the transmission efficiency can be very high for diffusers with a narrow radiation pattern and is superior to volume diffusers with a wider radiation pattern. Regarding the angular limits of surface structures and the lower count of interactions, surface diffusers do not reach perfect cosine characteristics.

The parameters of the diffusers are typically determined with far-field measurements. For surface diffusers, these parameters are usually scaled with the resolution/size of the structures. This makes it necessary to prove the chosen diffuser individually for the use case. A double-sided surface diffuser with a wide radiation pattern used by ams OSRAM is “Kimoto 100 PBU”, with a thickness of 125 micrometers.

Volume Diffusers

In volume diffusers, incoming light is scattered when it hits a scattering center within it. The scattering centers are typically microscopic small white particles. Depending on the design, each particle can generate a Lambertian reflection on its surface, which leads to multiple internal reflections and creates random light paths through a labyrinth of particles. The result is a nearly perfect cosine and wavelength-independent/achromatic characteristic even in near field. However, due to multiple Lambertian reflections, a high percentage of the light is also reflected to the input side of the diffusers. Due to this reflection, the transmission efficiency of cosine volume diffusers is smaller than 50%. A volume diffuser with nearly Lambertian characteristics used by ams OSRAM is “Lexan 8B28 – opaque white”, with a thickness of 250 micrometers.

The selection of a diffuser always depends on the use case, the irradiance on diffuser or sensor, and the needed flexibility of the setup.

For low light applications, a surface diffuser with high transmission and the widest radiation pattern as possible should be used. Narrowing the radiation pattern for higher transmission efficiency is only possible for detecting large and homogenous light sources (see chapter 5) or if the conditions for calibration are stable and equal to the measurement geometry. Under stable conditions, chromatic effects, etc. could be compensated by calibration. In applications under changing conditions regarding size, direction, and/or orientation of the light source, a volume diffuser with nearly Lambertian and achromatic characteristics is the best choice to create a sensor system that is not affected by the direction of incoming light.

Average Angular Response and Light Homogeneity

The average angular response of the AS7341 is related to the angle of incidence and it is limited to ±40° over all the channels. Due to the structured detector (4 x 4 array), the field of view is individual for each photodiode; almost symmetrical for the centered photodiodes and more asymmetrical for those in distance to the center. To avoid a blurred imaging of a light source or its position onto the sensors array the diffuser is also used (see Figure 10).

Regarding its characteristics, the diffuser also modifies the average angular response of the sensor system (AS7341 + diffuser). When using diffuser, which is not a perfect Lambertian and meets just the minimum scatter recommendation (see Figure), the angular response of the system will only have the same characteristics in the case of normal incidence. In the case of a tilted light incidence, the response may shift to an asymmetrical shape. This causes different color measurements in relation to the positioning light source and sensor and decreases the accuracy. To avoid such inaccuracies during calibration, it is necessary to illuminate the diffuser with homogeneous light over the hemisphere.

Additional Documents

The following list includes a selection of additional documents with more technical details for the AS7341 Sensor and its test kits. This list is not fixed and it is constantly changing. Ask us for new details.

For further information, please refer to the following documents:

1. ams-OSRAM AG, AS7341 11-Channel Multi-Spectral Digital Sensor (DS000504), Datasheet.

Revision Information

Changes from previous version to current revision v1-00 /Page

Initial version

• Page and figure numbers for the previous version may differ from page and figure numbers in the current revision.
• Correction of typographical errors is not explicitly mentioned.

Legal Information

Copyrights & Disclaimer

Copyright ams-OSRAM AG, Tobelbader Strasse 30, 8141 Premstaetten, Austria- Europe. Trademarks Registered. All rights reserved. The material herein may not be reproduced, adapted, merged, translated, stored, or used without the prior written consent of the copyright owner. Information in this document is believed to be accurate and reliable. However, ams-OSRAM AG does not give any representations or warranties, expressed or implied, as to the accuracy or completeness of such information and shall have no liability for the consequences of use of such information.

Applications that are described herein are for illustrative purposes only. ams-OSRAM AG makes no representation or warranty that such applications will be appropriate for the specified use without further testing or modification. ams-OSRAM AG takes no responsibility for the design, operation and testing of the applications and end-products as well as assistance with the applications or end-product designs when using ams-OSRAM AG products. ams-OSRAM AG is not liable for the suitability and fit of ams-OSRAM AG products in applications and end-products planned.

ams-OSRAM AG shall not be liable to recipient or any third party for any damages, including but not limited to personal injury, property damage, loss of profits, loss of use, interruption of business or indirect, special, incidental or consequential damages, of any kind, in connection with or arising out of the furnishing, performance or use of the technical data or applications described herein. No obligation or liability to recipient or any third party shall arise or flow out of ams-OSRAM AG rendering of technical or other services.

ams-OSRAM AG reserves the right to change information in this document at any time and without notice.

RoHS Compliant & ams Green Statement

RoHS Compliant: The term RoHS compliant means that ams-OSRAM AG products fully comply with current RoHS directives. Our semiconductor products do not contain any chemicals for all 6 substance categories plus additional 4 substance categories (per amendment EU 2015/863), including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, RoHS compliant products are suitable for use in specified lead-free processes. ams Green (RoHS compliant and no Sb/Br/Cl): ams Green defines that in addition to RoHS compliance, our products are free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material) and do not contain Chlorine (Cl not exceed 0.1% by weight in homogeneous material).

Important Information: The information provided in this statement represents ams-OSRAM AG knowledge and belief as of the date that it is provided. ams-OSRAM AG bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. ams-OSRAM AG has taken and continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals. ams-OSRAM AG and ams-OSRAM AG suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.

Contacts

Headquarters

• ams-OSRAM AG
• Tobelbader Strasse 30 8141 Premstaetten Austria, Europe
• Tel: +43 (0) 3136 500 0
• Please visit our website at: www.ams.com
• Buy our products or get free samples online at: www.ams.com/Products
• Technical Support is available at: www.ams.com/Technical-Support
• Provide feedback about this document at: www.ams.com/Document-Feedback
• For sales offices, distributors and representatives go to: www.ams.com/Contact
• For further information and requests, e-mail us at: ams_sales@ams.com

Read User Manual Online (PDF format)

Read User Manual Online (PDF format)  >>

Download This Manual (PDF format)

Download this manual  >>