![]() ![]() In most other cases, i.e., if time permits, the SNR can be improved by integrating longer. The limitations can be due to an intrinsically low signal, temporal variations in the sample structure, or source duration. The SNR can be the ultimate consideration in applications where the flux is very low during the allowable measurement period. Here, however, the discussion will be limited to noise sources associated with the detection system. ![]() The source itself has some instability, the spectrometer has some level of stray light, and the table may vibrate. There are many sources of noise that will affect the quality of a spectrum. Higher SNRs are usually required for quantitative analysis. A peak with a SNR of 4/1 may not look pretty but none-the-less, is unambiguous and may be acceptable for qualitative analysis. The signal-to-noise ratio (SNR) must be greater than 1/1 to distinguish a spectral feature from the noise. It is important to ensure that the signal from the sample exceeds the sum of the noise components. In light-starved applications, the collection optics, spectrograph options, and CCD detector configuration are all critical.Īll spectra have noise. The main goal of a spectrometric measurement system is to be able to distinguish the spectral features from the noise, within the time limits imposed by the phenomenon, and environmental or financial factors. All spectroscopic CCD systems have 16 bit analog to digitalĬonverters (ADC) limiting the measurable dynamic range to 65,535 to 1 or less. A typical scientific CCD detector has an intrinsic dynamic range of over 300,000 to 1. ![]() In spectroscopy, higher dynamic range is important for making measurements over a wide range of intensities. the ability to differentiate shades of gray, usually does not have to exceed 1,000 to 1. In most imaging applications the dynamic range, i.e. In spectroscopy, spatial resolution is not as critical as horizontal spatial resolution, which is mapped to spectral resolution, and is determined by the spectrograph. In imaging, spatial resolution is more important than dynamic range. The priorities for spectroscopic acquisition are different than for image acquisition. CCD cameras for spectroscopy are cooled to reduce dark noise. They also do not have masking for image transfer. Spectroscopic CCDs are often 25 mm or longer and have pixels around 25 μm square. Imaging CCDs typically are 6 mm x 4 mm with pixels smaller than 10 μm square. However, they incorporate CCD sensors which typically have larger pixels and are longer than the CCDs used for imaging applications. CCD detection systems specifically designed for spectroscopy are sometimes referred to as cameras. ![]()
0 Comments
Leave a Reply. |
AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |