When using an optical spectrum analyzer (OSA) to measure light propagating in free space, and because the input to an OSA is typically via a fiber optic connection, an adaptive fixture is often required.* This fixture, more commonly referred to as a jig, enables coupling of the light into an optical fiber. This application note introduces free space light measurement jigs as a recommendation for measuring the emission spectrum of a light source that propagates in free space or the optical transmission spectrum of an optical filter. It describes four types of jigs for light sources and one type for filters.
In recent years there has been a dramatic increase in optics-related R&D and manufacturing applications across multiple industries (e.g., telecom, biomedical, environmental monitoring, gas sensing/analysis) that necessitate advanced optical spectral measurements, and specifically, the measurement of light in free space.
Given the complexities of measuring free space light, the use of a specialized jig is typically employed to ensure that data is captured accurately and with the highest precision possible.
Figure 1: The AQ6373E Optical Spectrum Analyzer from Yokogawa Test&Measurement covers the visible wavelength range of 350 nm to 1200 nm and is designed for bio-photonics applications
When selecting the best jig type for a project, it is important to consider the target object, required coupling efficiency, and budget.
*1 The actual wavelength range is limited by the wavelength bandwidth of optical fibers and lenses
Table 1: Jig types L-1, L-2, L-3, and L-4 are used for light source measurements
*1 The actual wavelength range is limited by the wavelength bandwidth of optical fibers and lenses
Table 2: Jig type T-1 is used for optical filter measurement
L-1 jig types are used for general purpose light source measurement. Applicable for both divergent and collimated light, L-1 jigs are easy to use, low-cost, and enable precise optical alignment with XY-axis translation mount.
Considerations
Alignment Steps
Figure 2: Jig type L-1 component configuration
L-2 jig types are used for measurements relating to TO-CAN (divergent) light sources. Simple to use and low-cost, they utilize a cage system for easy optical alignment with the XY-axis translation mount.
Considerations
Alignment Steps
Figure 3: Jig type L-2 component configuration
L-3 jig types are used for measurements of divergent light with low coupling loss due to aspheric lenses or parabolic mirrors. They use a cage system plus two translation mounts for precise optical alignment.
Considerations
Alignment Steps
Optional Steps
Figure 4: Jig type L-3 component configuration
L-4 jig types measure divergent light with low coupling loss due to aspheric lenses or parabolic mirrors using a cage system plus two translation mounts for precise optical alignment.
Considerations
Alignment Steps
Optical Alignment
Figure 5: Jig type L-4 component configuration
Designed for large-diameter multimode fiber and using reflective optics, T-1 jig types measure the transmission characteristics of optical filters with low insertion loss over a wide wavelength range and do not require optical alignment adjustments.
Considerations
Figure 6. Jig type T-1 component configuration
Figure 7: Insertion loss measured with an AQ6374 OSA using 400 μm multimode fiber, peaks near 1400 nm are water vapor absorption spectrum (can be reduced using OSA purge feature)
Figure 8. Insertion loss measured with AQ6376 and AQ6377 OSA using 400 μm multimode fiber, peaks near 2700 nm and 4200 nm water vapor absorption spectrum (can be reduced using OSA purge feature), large noises between 4400 nm and 5000 nm due to sensitivity limitations (can be reduced using light source with high spectral power density)
A broadband light source is required to measure the transmission characteristics of optical filters. The four primary broadband light source types are amplified spontaneous emission (ASE), super luminescent diode (SLD), super-continuum (SC), and white light.
Figure 9: Wavelength bands and comparison of light sources
ASE Light Source
SLD Light Source
SC Light Source
White Light Source
Figure 10. Comparison of light sources
For jig types L-1, L-2, L-3, and L-4, optical fiber selection is made according to the measurement wavelength and required wavelength resolution.
Figure 11: Optical fiber examples
For jig type T-1, select a suitable optical fiber according to wavelength, required dynamic range, wavelength resolution, and light source. When selecting optical fiber, it’s important to note that even when multiple optical fibers are made of the same material, they can sometimes have different wavelength characteristics.
ASE, SLD, and SC Light Sources
White Light Source
Figure 12: Optical fiber examples
Viewer Card
Viewer cards visualize the irradiation point of infrared light and facilitate optical alignment. By moving the card back and forth in the direction of light propagation, it becomes possible to confirm the light is parallel via size change. Viewer card models differ depending on light source wavelength
Shearing Interferometer (Collimation Tester)
A shearing interferometer is used to determine if light is collimated (i.e., interference fringes are parallel to the reference line). A single-mode visible laser, such as a He-Ne laser, is used for collimation (Fabry-Perot lasers and broadband light sources do not produce interference fringes so single-mode fiber-coupled visible light sources can be used).
Alignment Disk
Like viewer cards, alignment disks visualize the irradiation point of infrared light to facilitate optical alignment. Additionally, they are compatible with a cage system
Depending on the source and application, there are multiple jig options and configurations available to measure the emission spectrum of light propagating in free space, as well the optical transmission spectrum of an optical filter. Whether constructing a straightforward optical arrangement or an intricate experimental system, various jig setups are available that enable customization precisely suited to your requirements. These setups encompass a spectrum of configurations, from basic spectrometer-based arrangements to sophisticated combinations that integrate optical fibers, collimators, and mirrors, to enable precise and accurate measurements.
*Please note these recommendations are applicable only to OSAs that do not have an internal connector and use a free space input (such as the AQ637x series) and are not applicable to OSAs with an internal input connector design (e.g., the AQ6380 OSA).
Der optische Spektrumanalysator AQ6370E deckt die gängigen Wellenlängen für die Telekommunikation ab. Er ist vielseitig einsetzbar, da er aufgrund des Freistrahleingangs für Single-Mode und Multi-Mode Anwendungen geeignet ist.
Der optische Spektrumanalysator AQ6373E ist in 3 Leistungs-Varianten erhältlich. Er eignet sich besonders für Messungen im sichtbaren Spektrum und für Laser wie sie in industriellen, biologischen und medizinischen Bereichen Anwendung finden.
Der optische Breitband-Spektrumanalysator AQ6374E deckt sowohl den Bereich des sichtbaren Lichts (380 bis 780 nm) als auch die in der Telekommunikation genutzten Wellenlängen ab. Er eignet sich für vielfältige Anwendungen sowie die Bewertung von Lichtwellenleitern.
Der optische Spektrumanalysator AQ6375E ist in drei Varianten erhältlich. Mit seinem breiten Messbereich bis ins nahe Infrarot ist er für Anwendungen in der Umweltsensorik, im medizinischen Bereich und für die Telekom-Wellenlängen geeignet.
Yokogawa gehört mit der Produktlinie der hochwertigen und innovativen optischen Spektrumanalysatoren (OSA) zu den weltweiten Marktführern bei der optischen Wellenlängen-Messtechnik. Auf der Basis unserer mehr als dreißigjährigen Erfahrungen in diesem Bereich ergänzen wir unsere OSAs nun mit optischen Wellenlängen-Messgeräten als komplementäre Lösung. Die optischen Wellenlängen-Messgeräte von Yokogawa erlauben schnelle, genaue und dennoch kostengünstige optische Wellenlängen-Messungen entsprechend den derzeitigen und künftigen Anforderungen und im Hinblick auf den weltweit schnell zunehmenden Datenverkehr in den Netzen.