Frequently Asked Questions (FAQs)
Technical Docs & Papers - FAQs
Solar Simulators
The below sections are answers to questions that we commonly receive about our solar simulator systems.
It takes less than one minute to change the lamp and less than five minutes to align the lamp.
A calibrated Reference Cell is created by exposing the cell to a known and calibrated standard one sun light source. The short circuit current (ISC) generated by the Reference Cell is noted under the standard conditions. Once this current value is established, then the Reference Cell is put under the SS light, the current generated is noted and compared to calibration value. If the generated current does not match the calibration value then the light intensity of the SS is adjusted until the generated current matches the calibration value. In general a Reference Cell should be made out of the same material as the cells that are to be tested. If this is not the case, then the spectral mismatch correction factors should be used for more accurate results.
For users that only have Solar Simulators (i.e. no IV Measurement system), a shunted Reference Cell can be used to calibrate the intensity of the Solar Simulator. The shunted Reference Cell has a resistor across the two electrodes of the cell. When the shunted Reference Cell is placed under the light, it generates a signal, typically in mV DC. The value of this resistor is selected such that the output of the Reference Cell is linearly proportional to the intensity of the light.
I-V Measurement Systems
The below sections are answers to questions that we commonly receive about our IV measurement systems.
The CCS uses Peltier cells to control the temperature. The temperature is usually controlled within 0.1 degree.
The standard system is not equipped with temperature sensor.
Yes the system has temperature compensation, whereby the measurement results can be normalized to 25°C.
There is no problem to make I-V corrections to Standard temperature using software procedures. The problem is to know cell’s true temperature. In such situation the only way is to use remote IR temperature sensor which is not too fast (usually it needs 1 or 2 sec for measurement).
The electronic circuitry should be calibrated periodically. Although the system maintains its calibration for a long period of time, those who are concerned should calibrate annually. The calibration involves using a calibrated voltage and current source. The value of the current-sensing resistor is determined and incorporated into the software as a conversion factor. Also, the value of the voltage division ratio is similarly determined and recorded.
The light intensity should be calibrated frequently. This is performed by measuring the electrical output of a reference cell and comparing the measurement result to the reference calibration value for the test conditions of interest. The lamp power should be adjusted until the reference cell measurement is matches its calibration value.
Data storage and data format is really minor problem – it can be adjusted to almost any user requirements.
Data back up can be done many different ways – back up to a CD or transfer by Intranet to another computer. There is no need to shut down the system for data backup.
Usually there are binary signals (TTL standard) that can be used for automation interface and sorting purposes. Number of signals depends on user requirements concerning number of sorting groups.
Currently it is not available. We plan to make it available in the future.
When measuring cells, there are several sources that may introduce variations in the measurements. First, the light source will have some variation, no matter how small, over time. Second, the cell characterization system will also have some variation over time. Third, the cell itself will have a variation in its performance even when there is no variation in the light source and cell characterization, and finally there may be some variation due to environmental factors, such as temperature etc. Despite all these factors, the variation in measured values are extremely small. See the paper titled “Advanced system for calibration and characterization of Solar Cells” by F. Granek and T. Zdanowicz.
All common data such as Isc, Voc, Im, Vm, Pm , FF, Eff, Rs and Rsh is provided. The system may include optionally procedures for extraction cell’s internal parameters corresponding to cell’s equivalent model to either so called single, double diode or variable diode model (i.e. SEM, DEM and VDEM, respectively).
A computer is supplied with the CCS. For lab and research environment we supply a regular PC. For production applications, we recommend an Industrial PC at a slightly higher cost.
The probes used are spring loaded “pogo stick” style probes. Some spare probes are included with the system as standard. The cost of replacement probes is nominal.
No special requirements; to start measurements a low vacuum source is needed. If thermal coefficients of cell need to be determined then a water source will be needed (this is rather lab and research option rather than production option). A single phase electrical outlet is required (can be either 115V/60 Hz or 230V/50 Hz as specified by customer). No special operating environment is needed.
The system does not need to be operated in a clean room environment. However, it should be operated in a clean environment.
One day for installation and training should be enough.
Yes the software can be customized to include production data in the data files.
The purpose of using the Solar Simulator is to predict the cell performance when the cells will be exposed to actual sun light. So if the Solar Simulator used exactly matches the sun light, then the prediction of the cell performance will be accurate. If however, the Solar Simulator is not an exact match with the sun light then there will be a difference in the predicted and actual cell performance. Class A system is not an exact match with the sun light, but it is a much closer match than Class B. In the end the decision on which system to use is based on the cost of the Solar Simulator and cost of any problems resulting from a mismatch between predicted and actual preformance of the cell.
Yes the cell characterization is automated. The testing is initiated by pressing a key on the computer keyboard. The testing can be initiated externally as well. However, the loading and unloading of the sample is manual. The cell characterization system is capable of being interfaced with a cell transfer automation system and sort the cells in to nine (9) different categories.
Yes the system includes four probes for making the electrical contact with the cell for testing. For production use, a different probing would be recommended based on customer’s needs.
If you have a question not answered above, please send us your question at support@photoemission.com and we will send you a reply at the earliest.