An optical spectrum analyzer is a measuring instrument that resolves the wavelength components of photonics devices such as semiconductor lasers and fiber lasers to evaluate their wavelength characteristics. The AQ6377 will be used to enhance optical devices in the 5-?m band and accelerate their use in environmental measurement and other fields.
Development Background
Recently, laser absorption spectroscopy*3 has entered wide use in the environmental measurement field for the detection of gases such as carbon oxides (COx), nitrogen oxides (NOx), and hydrocarbons (CxHy). Although near-infrared semiconductor lasers have been used as the optical source in such applications, there is an increasing need for mid-infrared lasers because these gases absorb more light at longer wavelengths. The wavelength range around 5 ?m is ideal for such measurements, and devices such as interferometer-type measurement instruments and large-scale measurement systems with spectrometers are available that use 5-?m semiconductor lasers to measure optical spectra in this range; however, these have disadvantages such as narrow dynamic range and low wavelength resolution that negatively impact measurement accuracy. There is thus a strong demand for compact, high-performance optical spectrum analyzers.
Since entering the optical spectrum analyzer market in 1980,
Product Features
1. Industry-leading measuring range
The AQ6377 features a dynamic range of 73 dB and a close-in dynamic range*4 of 50 dB, which are 2,000 times and 10 times greater, respectively, than the dynamic ranges of interferometer-type instruments operating in the 5-?m band. No other instrument on the market offers such high performance*5, which enables the evaluation of the side mode characteristics of semiconductor lasers.
2. Industry's highest wavelength resolution
The wavelength resolution of the AQ6377 is an industry-leading 200 pm*6, which is three times that of interferometer-type instruments operating in the 5-?m band.
3. Accurate measurement of optical spectra
The AQ6377 comes with two additional functions. The first is a function that removes water vapor, which absorbs light at certain wavelengths, from the spectrometer. The second is a function that eliminates artifacts from higher-order diffracted light, a phenomenon intrinsic to all spectrometers in which wavelengths two to three times longer than those of incident light are generated.
Major Target Users
Universities, research institutes, and manufacturers of active and passive optical devices that are engaged in the environmental sensing field
Main Applications
- Emission spectrum evaluation for semiconductor lasers, fiber lasers, and broadband light sources
- Measurement of wavelength transmission characteristics for optical filters such as a fiber bragg grating (FBG)*7
*1 A technique whereby light is dispersed by passing it through a diffraction grating and then directed through a narrow opening to extract a specific range of wavelengths
*2 Based on a
*3 The use of a laser to irradiate molecules, which, depending on their type, will absorb light of a particular wavelength. This principle is used to analyze the optical spectrum and quantitatively assess molecules in the gas phase.
*4 An indicator of the ability to resolve a weaker signal that is very close (in wavelength) to a stronger signal
*5 Based on a
*6 Based on a
*7 A device that utilizes periodic variations in the refractive index to reflect a certain wavelength in an optical fiber
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Founded in 1915,
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