In wavelength division multiplexing (WDM) systems, high-frequency modulated signals with complex formats are densely packed within the WDM channel. These systems require high stability in wavelength (or frequency) and power. Therefore, long-term stability evaluations, such as temperature cycle tests and high load tests, are essential not only for WDM transmission systems but also for the semiconductor lasers (LD) and optical transceivers that comprise these systems.
A primary reason for these tests is to verify the thermal stability and measurement drift of optical components in an environmental chamber.
Most Yokogawa Optical Spectrum Analyzer (OSA) models simplify long-term measurements using built-in data logging and programming functions, eliminating the need for an external PC. The data logging function enables continuous optical spectrum measurement, analysis, and data saving under preset conditions.
During analysis, key parameters such as WDM (peak wavelength, peak level, OSNR) and DFB-LD (SMSR) can be evaluated, with each parameter value recording up to 10,000 data points per peak wavelength (channel). These recorded values are displayed along with their maximum and minimum values in a logging table or graph, with the vertical axis representing the amount of change and the horizontal axis representing time. By moving the cursor, users can display the optical spectrum waveform at specific times, allowing for the observation of both analysis values and temporal changes in the optical spectrum.
One of the main challenges in performing long-term stability tests is the need for repetitive and precise measurement procedures, which can be time-consuming and prone to human error if done manually. Additionally, setting up complex measurement sequences often requires software engineering, which can require an external PC, specialized skills and additional costs.
Yokogawa's internal OSA macro programming function addresses these challenges by allowing users to create and register a series of measurement procedures in advance, enabling automatic measurement execution. No programming expertise is required. Creating a program is straightforward, as users can simply select commands corresponding to the OSA keys, mimicking actual OSA operation. This intuitive process ensures that even those without programming knowledge can easily set up and execute complex measurement procedures.
For more sophisticated setups, advanced commands for loop control, condition judgment, variables, arithmetic operations, parameter input, and screen output are also available, making the programming function versatile and powerful while still user-friendly.
High Performance LONG WAVELENGTH
The AQ6375B is a bench-top optical spectrum analyzer covering the long wavelengths, 1200 to 2400 nm, with the added benefits of gas purging input ports / output ports, a built-in cut filter for high order diffracted light, and a novel double speed mode which increases the sweep speed up to 2 times compared to the standard sweep mode.
High Performance LONG WAVELENGTH
The AQ6375E covers not only telecommunication wavelengths, but also the SWIR region which is often used for environmental sensing and medical applications.
・Lineup of 3 models [Standard, Extended and Limited]
・Covers wavelengths
1200 to 2400 nm [Standard, and Limited]
1000 to 2500 nm [Extended ]
MWIR WAVELENGTH with internal gas purge and cut filter
The AQ6376 is the latest version of our bench-top optical spectrum analyzer extending the wavelength coverage well beyond the NIR range of our previous models into the MWIR region from 1500 to 3400 nm.
Popular applications include the detection of gases such as carbon oxides (COx), nitrogen oxides (NOx), and hydrocarbon gas (CxHy) for environmental studies.
MWIR WAVELENGTH with internal gas purge and cut filter
The AQ6376E is the latest version of our bench-top optical spectrum analyzer extending the wavelength coverage well beyond the NIR range of our previous models into the MWIR region from 1500 to 3400 nm.
Popular applications include the detection of gases such as carbon oxides (COx), nitrogen oxides (NOx), and hydrocarbon gas (CxHy) for environmental studies.
Measures the power intensity of light across different wavelengths in the electromagnetic spectrum.