IS6-C-UV-2.5"(for collimated beams)

7Z02485
 
Beschreibung: 

Die IS6-C-UV-2,5'' ist eine Ulbrichtkugel mit einem Durchmesser von sechs Inch (ca. 15 cm), die mit einem Silizium-Sensor zur Messung großer gebündelter Strahlen ausgestattet ist. Die IS6-C-UV-2,5'' wird mit einem UV-Sensor geliefert, der von 200 bis 1100 nm kalibriert ist und bis zu 2W messen kann.

Specification

  • Ø63.5mm
  • 200-1100nm
  • 300nW-2W
  • Ø154 (mm)
  • 0.1mJ
  • 2kW/cm²
  • N.A.
  • 2W
  • ±15 deg
  • ±1%
  • N.A.
  • CE, China RoHS
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Drawing

FAQ

Integrating spheres are used when you have divergent light sources. How do they work?

Integrating Sphere Theory
Integrating spheres are used when we have divergent light sources. As shown in the illustration, an integrating sphere has its inner surface coated with a surface that highly reflects (typically 99%) in a scattering, nonspecular way. Thus when a divergent beam hits the walls of the integrating sphere, the light is reflected and scattered many times until the light hitting any place on the walls of the sphere has the same intensity. 

A detector placed in the sphere thus gets the same intensity as anywhere else and the power the detector detects is thus proportional to the total incident power independent of the beam divergence. (The detector is so arranged that it only sees scattered light and not the incident beam). An ideal integrating sphere has a surface with reflective properties are Lambertian. This means that light incident on the surface is scattered uniformly in all directions in the 2pi steradians solid angle above the surface. The surface used by Ophir closely approximates a Lambertian surface.

3A-IS Series
The 3A-IS series has two 50mm integrating spheres in series with a photodiode detector. The two series spheres scramble up the light very well thus giving output very independent of incident beam divergence angle. The two spheres in series also insure that the light hitting the detector is greatly reduced in intensity thus allowing use up to 3 Watts even though photodiodes saturate at about 1mW. There are two models, the 3A-IS with a silicon photodiode for 400 – 1100nm and the 3A-ISIRG with an InGaAs detector for 800 – 1700nm

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Are there any special problems with the calibration stability of integrating sphere sensors?

The Ophir integrating sphere sensors, models 3A-IS and 3A-IS-IRG have a white diffuse reflecting coating on the inside of the integrating sphere. The sensitivity of the sensor is quite sensitive to the reflectivity of the coating. If the coating absorption goes up 1%, it can cause a 5% change in reading. Therefore, care must be taken not to soil or damage the white coating of the sensors. Also it may be a good idea to send the sensors for recalibration yearly.

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When using the fiber optic adaptor, how do we handle power loss due to the fiber relative to calibration?

All Ophir power meters, including photodiode power meters, have an air gap between the fiber tip and the sensor. Therefore they measure the power emitted by the fiber into the air and do not take into account any reflection losses there are in the fiber. Therefore, if in actual use, the fiber will be coupled with no loss to another element, then the losses should be added to the reading. These losses are usually about 4%. Thus if the reading on the Ophir meter is say 100mW, then in lossless use, the real power will be 104mW.

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Do I need to recalibrate my instrument? How often must it be recalibrated?

Unless otherwise indicated, Ophir sensors and meters should be recalibrated within 18 months after initial purchase, and then once a year after that.

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Among the Integrating Sphere accessories offered, there are “Port Plugs” (white), and “Port Covers” (black). What’s the difference?

An unused port should be closed, to prevent unwanted light from entering the sphere. Closing it with a diffuse white port plug, however, adds the surface area of that plug to the (diffuse white) effective area of the sphere that is doing the “integrating”. For a calibrated integrating sphere sensor, this change in the behavior of the sphere changes its calibration, and results in incorrect readings. In such applications, a black “Port Cover” should be used.

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How much variation in water temperature or flow rate is allowed in Ophir water cooled sensors?

Ophir water cooled sensors measure the heat flow across the thermopile disc and therefore are quite insensitive to the water temperature or flow rate within the given specified limits. However, sudden changes in the water temperature or water flow rate can cause a disturbance to the reading until the flow rate/temperature stabilizes again. Therefore we specify in our water cooled sensors that the water temperature should not change faster than 1C/min. Likewise, sudden changes in flow rate (e.g. switching another device connected to the same water line on and off) can results in temporary disturbances in the power reading.

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There are several models of IS6 integrating sphere detectors. how can I select the right one?

There is a simple to use selection guide.

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The IS6 integrating spheres have a specified “Sensitivity to beam size” and “Sensitivity to beam divergence”. What is that?

In general, as the divergence angle of the beam entering the integrating sphere increases - and as its diameter increases – the assumptions on which we base the sphere’s performance (infinite reflections inside the sphere walls, perfectly uniform distribution of light inside the sphere, etc.) become less correct. We therefore specify the maximum beam divergence (such as ± 60⁰), and we also state the maximum possible change in reading caused by change in beam size. In fact, we also state in the data sheet that the maximum additional uncertainty due to beam size is only ±1% for beam divergence < 30⁰, and ±3% for beam divergence > 30⁰. To give this more meaning: Basically, if you measure the power using a beam that is a few mm in diameter, that has a relatively small divergence angle, and is centered on the sphere’s input port aperture, you can safely ignore this additional uncertainty.

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Videos

Integrating Spheres: Overview Integrating Spheres: Overview
Measuring beams coming out of a fiber Measuring beams coming out of a fiber Measuring beams coming out of a fiber

When you measure a beam coming out of a fiber, there are some parameters that have a different meaning than they do when referring to "regular" beam measurements. This video clarifies some issues you'll need to keep in mind.

Measuring Power of LEDs: UV, Visible and NIR Measuring Power of LEDs: UV, Visible and NIR Measuring Power of LEDs: UV, Visible and NIR

Measuring the emitted power of an LED can be tricky; it is different in some important ways from measuring the power of a laser beam. This video shows you how to use the Ophir 3A-IS Integrating Sphere Sensor, along with the Auxiliary LED accessory, to easily make accurate measurements in LED applications.

Calibration Factors Calibration Factors Calibration Factors

When a power/energy meter is in "Calibrate" mode, various "Factors" are displayed to the user. This video explains the meaning of each of these factors.

If your application requires measurement of a widely diverging beam, an integrating sphere might be the right solution.
Learn what Integrating Spheres are, what they help you do, and see the range of solutions available.

Tutorials

Tutorials and Articles

Integrating Sphere Fundamentals an Applications

Introduction Weiterlesen...

Measuring Power of Divergent Beams with Integrating Sphere Sensors

An integrating sphere is used to measure a divergent light source. As shown in the illustration, an integrating sphere has its inner surface coated with a surface that highly reflects (typically 99%) in a scattering, nonspecular way. Thus when a divergent beam hits the walls of the integrating sphere, the light is reflected and scattered many times until the light hitting any place on the walls of the sphere has the same intensity.

 Weiterlesen...

Measuring LED Power and Irradiance with Calibrated Photodiodes

In many industries LEDs are replacing traditional broadband light sources such as mercury, deuterium, Xenon, and quartz-halogen lamps. Systems and applications transitioning to LEDs are reengineered in terms of optics, electronics, heat management and more. Similarly, the equipment used by professionals to measure the output of these sources needs to be fitted for measuring LEDs.

 Weiterlesen...

Accessories

Customers that purchase the above items also consider the following items. Ophir-Spiricon meters and sensors include a standard manufacturers warranty for one year. Add a one year Extended Warranty to your meter or sensor, which includes one recalibration.

See specification sheet for details on which accessories are supplied with sphere.