ISD-5P-SP

Need of Optical Power Meters

Pulsed laser diodes, LiDAR laser, VCSEL and pulsed LEDs used in range finders, environmental scanners and image capture emit pulses with a few nanoseconds length of very high peak power. To measure the temporally resolved pulse shape fast detectors (short rise time) and optical meters are required. These are usually small-area photodiodes with diameters of sometimes significantly less than 1 mm. Technical details regarding rise time and pulse shape measurements with photodiodes can be found for example in our knowledge portal. The small detector area of the photodiodes results in metrological limitations: 

• The extent of the laser spot is larger than the active area of ​​the photodiode and thus does not allow measurement of the radiant power (W). Thus, no measurement of the radiant power (W) is possible with such a photodiode alone.
• The position of the photodiode in the laser spot is critical because of possible modes (inhomogeneous laser spot).
• Very small photodiodes cannot be calibrated absolutely.
• Attachment optics used to focus the laser spot on the photodiode surface cannot be calibrated.
• The electronic wiring of the photodiodes required for short pulse lengths further limits  the calibration capability.

With the ISD-xx-SP-series of optical power meters in combination with the P-9710 series or P-21 series optometers (current amplifier), Gigahertz-Optik provides a way to determine the absolute radiometric peak performance of pulsed lasers and pulsed LEDs.

To overcome the limitations of pure photodiodes, a technology based on a small integrating sphere and two complementary photodiodes is used.

Function and Setup of the Optical Power Meter of the ISD-xx-SP Series

The detector incorporates two photodiodes within a compact integrating sphere assembly. The first photodiode has a short rise time and hence, in conjunction with a sufficiently fast oscilloscope, allows the measurement of the relative time resolved pulse shape (pulse length, half-width, peak power). The second photodiode measures the absolute pulse energy (in joules) of a single pulse or pulse train. The evaluation is carried out by an optometer of the P-9710 or P-21 series according to the pulse-stretching method. The absolute peak power can be calculated from the pulse energy and the relative pulse shape. Thus, the short duration light signal can be completely characterized. 

The integrating sphere with a diameter of 50 mm offers a measuring aperture of 10 mm (-V01: 7mm) diameter and can be calibrated to measure the absolute radiant power (W). Because of the small diameter of the integrating sphere, the temporal pulse deformations (pulse-stretching-effect of integrating spheres) are small compared to integrating spheres with larger diameters. As a result, pulses of a few nanoseconds pulse length are hardly deformed and can be measured in a time-resolved manner. The sphere itself, the photodiodes and the electrical circuit are housed and shielded by a high quality CNC-machined aluminium housing. For virtually no pulse deformation effects, the ISD-1.6-SP-Vxx, which is only 16 mm in diameter, is ideal (5 mm entrance port). We offer both spheres with 7 mm aperture for Eye-Safety measurements for lasers according IEC/EN 60825-1 and 2006/25/EC. For higher powers and a larger input port with 20 mm, the ISD-10P-SP is available.

The optional oscilloscope is connected via a BNC connector. The optometer is connected via a 2 m cable with  a multi-pin connector in which the calibration data are stored. 

The integrating sphere also offers two additional ports. For example, a spectrometer for measuring the wavelength and an auxiliary lamp for compensating for possible influences of the back reflection through the sample at the measurement port(self-absorption correction) can be connected. Ideal suited could be also one of our BTS2048 Series high end spectroradiometer.

Because of its small diameter, the sphere factor of the integrating sphere is relatively small. As a result, the permissible beam divergence in the version with a 7 mm measuring opening is additionally limited compared to the 5 mm version.

Two-Photodiode-Technology

High speed integrating spheres which are equipped with Gigahertz-Optik’s two-diode technology offer two photodiodes mounted on the sphere. A traceable calibrated photodiode is accurately measuring the total pulse energy. The second photodiode is performing a temporal characterization of the pulse and will deliver its relative pulse shape as result. With both results combined mathematically, the pulse can be completely characterized regarding all important parameters (pulse form, peak power, average power).

Data Evaluation by Powerful Optical Meters

Gigahertz-Optik offers various optometers, or optical meters called, with the required "pulse energy" measurement function for measuring the pulse energy of short pulse signals:

P-9710 (Version-2): Single-channel optometer with manual triggering of the measurement

P-9710 (Version-4): Single-channel optometer with TTL trigger input for triggering the measurement

P-2000: two-channel optometer

P-9801: Eight-channel optometer 

P-21: Touchscreen Single-channel optomter with manual or trigger input for triggering the measurement

To evaluate the time resolved pulse shape, the user must provide a sufficiently fast oscilloscope or one of our fast Transient Recorders.

Traceable Calibration with optional ISO17025 Certificates

The factory calibration of the spectral sensitivity of the pulse Energy detector is performed by the ISO/IEC 17025 calibration laboratory for optical radiation measurements at Gigahertz Optik GmbH. The principle of the pulse-stretch-method allows the calibration of the detector in CW operation. The CW-calibration is fully traceable.  

Optical Meter Applications

The application areas of the detector can be found, for example, in the development and quality assurance (on- and in-line) of pulsed laser diodes, LiDAR laser, VCSEL and pulsed LEDs as well as in the end application of such light sources.