Spectral transmittance measurement

  • Thread starter Thread starter MG_xy
  • Start date Start date
  • Tags Tags
    Measurement
AI Thread Summary
To measure spectral transmittance accurately, it is essential to account for both the light source spectrum and the photodiode's responsivity. Calibration of the photodiode across the relevant spectrum is crucial, especially when using a monochromator to select specific wavelengths. Understanding the light source's spectrum, whether it’s a black body for incandescent sources or another type, aids in correcting measurements. The process involves recording transmittance at 100% and 0% conditions before analyzing the sample. Proper calibration ensures reliable results in spectral transmittance experiments.
MG_xy
Messages
10
Reaction score
0
Dear all,
I am new in this forum; from a first sight I realized that you can help me to clarify a doubt.
My experiment requires the measurement of spectral trasmittance of a simple by using a white light source (400-800 nm) and a silicon photodiode. I know that a proper measurement require to record first white and black illumination condition (100% and 0% transmittance) and to refer the measurement of the sample to this two measurement.
My doubt is how to do the measurement by taking into account the spectrum of the light source and the responsivity of the photodiode.
Thank you in advance

Maria
 
Physics news on Phys.org
You can correct for the spectrum of the source if you know what it is. For incandescent, you can use black body spectrum. Other sources can be more or less complicated.

The photodiode should first be calibrated across the spectrum. Is there a filter somewhere in the setup?
 
Thank you K^2,
I am using a monochromator to select specific wavelengths and I know the spectrum of the source. My doubt is how to calibrate across the spectrumby taking into account the responivity of the photodiode practically.
 

Thread 'Why can't Solar panels be hemispherical, or a curved strip type?'

comparing a flat solar panel of area 2π r² and a hemisphere of the same area, the hemispherical solar panel would only occupy the area π r² of while the flat panel would occupy an entire 2π r² of land. wouldn't the hemispherical version have the same area of panel exposed to the sun, occupy less land space and can therefore increase the number of panels one land can have fitted? this would increase the power output proportionally as well. when I searched it up I wasn't satisfied with...
View full post »

Similar threads

I Recreating Spectral Response from 6-Channel Color Sensor
Replies
6
Views
3K
I Gases: Not Required to Be Blackbodies
Replies
19
Views
17K
Measure optical power with spectrometer
Replies
9
Views
5K
Problem involving interference and medium with index n
Replies
1
Views
1K
Infrared thermometry remote sensing
Replies
5
Views
2K
B Infrared Detectors & The 2nd Law of Thermodynamics
4
Replies
152
Views
9K
A Two-Photon Excitation: Theory and Applications
Replies
3
Views
2K
Interference of light, emission spectroscopy prac. report
Replies
1
Views
2K
A How to compute phase gradient from Snell's law?
Replies
1
Views
2K
Importance of Angle in Light Spectrometry for Reflectance Measurements
Replies
4
Views
1K

Hot Threads

Recent Insights

Back
Top