Talk:Solar simulator
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Requested move
edit- The following discussion is an archived discussion of a requested move. Please do not modify it. Subsequent comments should be made in a new section on the talk page. No further edits should be made to this section.
The result of the move request was: moved. ErikHaugen (talk | contribs) 18:22, 12 January 2012 (UTC)
Solar Simulator → Solar simulator –
Per WP:MOSCAPS ("Wikipedia avoids unnecessary capitalization") and WP:TITLE, this is a generic, common term, not a propriety or commercial term, so the article title should be downcased. Lowercase will match the formatting of related article titles. Tony (talk) 07:38, 4 January 2012 (UTC)
- The above discussion is preserved as an archive of a requested move. Please do not modify it. Subsequent comments should be made in a new section on this talk page. No further edits should be made to this section.
Precise Numbers of Error Tolerances
editThe ASTM reference [1] shows the temporal irradiance instability as less than and equal 2% (for small areas and 3% for large areas) and not as 0.5% as was stated earlier. I apologize for editing even though it was requested not to edit this section. However I felt this was important - as it turned out to be a big problem when installing a AAA solar simulator and we were aiming at a <0.5% as stated earlier. Even the PET tech standardization have referred to the same ASTM standard of 2%. If there are any issues please raise alarms since these are critical numbers not to be thrown around casually. Even the Class B has been changed from 2% to 5% according to the ASTM E927 - 10 standards [Vijay V]
— Preceding unsigned comment added by Vijay Venugopalan (talk • contribs) 19:19, 17 May 2013 (UTC)
LED reference
editCould someone put a reference for using LEDs as a source? — Preceding unsigned comment added by 130.184.253.75 (talk) 16:31, 22 May 2014 (UTC)
Large update and expansion suggestions for Solar Simulator Article
editThis edit request by an editor with a conflict of interest has now been answered. |
Extended content
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I have broken down a number of large-scale suggested changes by section below. Changes to the Introductionedit
The current introduction does not sufficiently include all major areas where solar simulators are used, nor does it adequately cite sources/examples of these applications.
Changes to 'Classification' Sectionedit
Each dimension is classified in one of three classes: A, B, or C. The specifications required for each class are defined in Table 1 below. A solar simulator meeting class A specifications in all three dimensions is referred to as a Class A solar simulator, or sometimes a Class AAA (referring to each of the dimensions in the order listed above).[16]
The solar simulation spectrum is further specified via the integrated irradiance across several wavelength intervals. The percentage of total irradiance is shown below in Table 2 for the standard terrestrial spectra of AM1.5G and AM1.5D, and the extraterrestrial spectrum, AM0.
These specifications were primarily intended for silicon photovoltaics, and hence the spectral range over which the intervals were defined was limited mainly to the absorption region of silicon. While this definition is also adequate for several other photovoltaic technologies, including thin film solar cells constructed from CdTe or CIGS, it is not sufficient for the emerging sub-field of concentrated photovoltaics using high-efficiency III-V semiconductor multi-junction solar cells due to their wider absorption bandwidth of 300–1800 nm.
The standards specifying performance requirements of solar simulators used in photovoltaic testing are IEC 60904-9[17], ASTM E927-19[18], and JIS C 8912[19] These standards specify the following dimensions of control for light from a solar simulator:
A solar simulator is specified according to its performance in the first three of the above dimensions, each in one of three classes: A, B, or C. (A fourth classification, A+, was introduced by the 2020 edition of IEC 60904-9 and only applies for solar simulators evaluated in the spectral range of 300 nm to 1200 nm[17]). For ASTM E927, if a solar simulator falls outside the A,B,C criteria, it is considered Class U (unclassified)[18]. Although these standards were originally defined specifically for photovoltaic testing, the metrics they introduced have become a common way of specifying solar simulators more broadly in other applications and industries[20][21][22]. The ASTM E927-19 specifications required for each class and dimension are defined in Table 1 below. A solar simulator meeting class A specifications in all three dimensions is referred to as a Class AAA solar simulator (referring to the first three dimensions listed above).[18]
The ASTM E927 standard specifies that whenever this triple-letter format is used to describe a solar simulator, it needs to be made clear which classification applies to each solar simulator metric[18] (e.g. a Class ABA solar simulator needs to make clear which parameter(s) are Class A vs B). The IEC 60904-9 standard specifies that the three letters must be in order of spectral match, non-uniformity, and temporal instability[17].
Updated links to the solar simulator standards need to be provided, as well as the inclusion of the JIS C 8912 standard which was absent. The recent update to the IEC 60904-9:2020 standard added spectral coverage and spectral deviation metrics which needed to be added as well, along with the definition of a new A+ classification which required clarification of which spectral range it must be applied to. Since spectral coverage and spectral deviation are optional metrics at this time, clarity was needed around which metrics are mandatory to achieve Class AAA classification. Spectral content needed to be made clearly equivalent to spectral match since that is how it is referenced in the standards. Also clarified details around Class AAA nomenclature which are not necessarily consistent in the nomenclature. The content referring to spectral match is recommended to be moved to its own subsection.
See in-line citations above. New subsection under 'Classification': 'Spectral Match'edit
This subsection did not previously exist, but I will show the original content that will be moved and included in this new subsection. Original:
These specifications were primarily intended for silicon photovoltaics, and hence the spectral range over which the intervals were defined was limited mainly to the absorption region of silicon. While this definition is also adequate for several other photovoltaic technologies, including thin film solar cells constructed from CdTe or CIGS, it is not sufficient for the emerging sub-field of concentrated photovoltaics using high-efficiency III-V semiconductor multi-junction solar cells due to their wider absorption bandwidth of 300–1800 nm.
A solar simulator’s spectral match is computed by comparing its output spectrum to the integrated irradiance in several wavelength intervals. The reference percentage of total irradiance is shown below in Table 2 for the standard terrestrial spectra of AM1.5G and AM1.5D, and the extraterrestrial spectrum, AM0. Below is a plot of these two spectra. A solar simulator’s spectral match ratio, (i.e. ratio of spectral match), is its percentage output irradiance divided by that of the reference spectrum in that wavelength interval. For example, if a solar simulator emits 17.8% of its total irradiance in the 400 nm - 500 nm range, it would have a in that wavelength interval of 0.98. If a solar simulator achieves a spectral match ratio between 0.75 and 1.25 for all wavelength intervals, it is considered as having class A spectral match.
These wavelength intervals were primarily intended for the solar simulator application of testing silicon photovoltaics, hence the spectral range over which the intervals were defined was limited mainly to the originally-developed absorption region of crystalline silicon (400 nm - 1100 nm). The solar simulator standards have some requirements for where the illumination spectrum must be measured. For example, the IEC 60904-9 standard requires that the spectrum be measured at 4 different locations in a pattern given below[17]. Recent material science developments have expanded the spectral responsivity range of c-Si, multi-c-Si and CIGS solar cells to 300 nm - 1200 nm[17]. Therefore, in 2020, the IEC 60904-9 standard introduced a new Table of wavelength intervals (given in Table 3 below) aimed to match solar simulator output to the present needs of a wide variety of photovoltaic devices[17].
For accurate spectral data outside the above-mentioned ranges, the data tables in ASTM G173 (for AM1.5G and AM1.5D)[23] and ASTM E490 (for AM0)[24] can be used as reference, but the specifications of solar simulators unfortunately do not yet apply to anything outside 300 nm to 1200 nm for AM1.5G, and 300 nm to 1400 nm for AM0. Many solar simulator manufacturers produce light outside these regions, but the classification of light in these external regions is not yet standardized.
This topic is large enough to merit its own subsection. Added how the ratio of spectral match is computed in order for the spectral match classification to be determined. Corrected percentage values to the latest values from the standards. Added required detail that measurements need to be made in multiple locations for a valid spectral match measurement, and updated context and information around the previous comments about photovoltaic technology types and the applicability of solar simulators.
New subsection under 'Classification': 'Spatial Non-uniformity'edit
Here is the array of normalized short-circuit current values detected by a solar cell or array of solar cells. The three solar simulator standards have slightly different requirements for how the array of measurements is gathered for computing spatial non-uniformity. ASTM E927 specifies that the illumination field must be measured at a minimum of 64 positions. The area of each test position, , is the illumination test area divided by the number of positions. The area of the detector used must be between 0.5 and 1.0 of [18].
Specification of how to measure and calculate spatial non-uniformity should be added in order for a reader to understand how a solar simulator is classified, similar to the provided explanations for how to compute spectral match.
New subsection under 'Classification': 'Temporal Instability'edit
Here is the array of measurements gathered over the period of data acquisition. The solar simulator standards do not specify the required time interval or sampling frequency in absolute terms.
This subsection is needed to inform readers how a solar simulator can have its temporal instability classified, similar to the explanations provided for how to calculate spectral match.
New subsection under 'Classification': 'Spectral Coverage'edit
This subsection is needed to inform readers how a solar simulator can have its spectral coverage calculated, similar to the explanations provided for how to calculate spectral match.
New subsection under 'Classification': 'Spectral Deviation'edit
This subsection is needed to inform readers how a solar simulator can have its spectral deviation calculated, similar to the explanations provided for how to calculate spectral match.
Changes to 'Types of solar simulators' sectionedit
The second type of solar simulator is the flashed simulator which is qualitatively similar to flash photography and use flash tubes. With typical durations of several milliseconds, very high intensities of up to several thousand suns are possible. This type of equipment is often used to prevent unnecessary heat build-up in the device under test. However, due to the rapid heating and cooling of the lamp, the intensity and light spectrum are inherently transient, making repeated reliable testing more technically challenging. The temporal stability dimension of the standard does not directly apply to this category of solar simulators, although it can be replaced by an analogous shot-to-shot repeatability specification. The third type of solar simulator is the pulsed simulator, which uses a shutter to quickly block or unblock the light from a continuous source. This category is a compromise between the continuous and flash, having the disadvantage of the high power usage and relatively low intensities of the continuous simulators, but advantage of stable output intensity and spectrum. The short illumination duration also provides the benefit of the low thermal loads of flashed simulators. Pulses are typically on the order of 100 milliseconds up to 800 milliseconds for special Xe Long Pulse Systems. Those systems are being offered for different segments such as quality control in production for solar cells and modules as well as independent laboratories or manufacturer R&D. Laboratory systems typically offer enhanced functions like temperature cycling and configurable irradiation levels. [36] New: Solar simulators can be divided into two different categories according to their emission duration: continuous (or steady-state), and flashed (or pulsed). Solar simulators are also sometimes categorized according to the number of lamps used to generate the spectrum: single-lamp or multi-lamp[37].
There is enough to discuss about each type of solar simulator that the information should be moved to their own subsections. Furthermore, there is no distinction between 'flashed' and 'pulsed' solar simulators in the standards, so the content around 'pulsed' solar simulators should be removed. Shutters for solar simulators are an optional accessory that do not bring about a new classification.
See in-line citations above. New subsection under 'Types of solar simulators': 'Continuous or Steady-State Solar Simulators'edit
This text should be given its own subsection, and the examples of solar simulator manufacturers removed to put into a list at the end of the entire article. Original: The first type is a familiar form of light source in which illumination is continuous in time. The specifications discussed in the previous section most directly relate to this type of solar simulator. This category is most often used for low intensity testing, from less than 1 sun up to several suns. In this context, 1 sun is typically defined as the nominal full sunlight intensity on a bright clear day on Earth, which measures 1000 W/m2. Continuous light solar simulators may have several different lamp types combined (e.g. an arc source and one or more halogen lamps) to extend the spectrum far into the infrared. [25] Examples of low-intensity and high-intensity continuous solar simulators are available from Solar Light Company, Inc. (inventor of the original solar simulator in 1967,) Atonometrics,[26] Eternal Sun,[27] TS-Space Systems,[28] WACOM,[29] Newport Oriel,[30] Sciencetech,[31] Spectrolab,[32] Photo Emission Tech,[33] Abet Technologies,[34] infinityPV [35] New: The first type is a familiar form of light source in which illumination is continuous in time, also known as steady-state. The specifications discussed in the previous sections most directly relate to this type of solar simulator. This category is most often used for low intensity testing, from less than 1 sun up to several suns. The total integrated irradiance for the AM1.5G spectrum is 1000.4 (280 nm to 4000 nm bandwidth)[23] which is often referred to as ‘1 sun’. Continuous light (or Continuous-Wave, CW) solar simulators may have several different lamp types combined (e.g. an arc source and one or more halogen lamps) to extend the spectrum far into the infrared. [25]
Examples of solar simulator manufacturers do not belong in this section, and clutter the information being presented. The definition of 1 sun needs to be less ambiguous as it has strict definitions.
See in-line citations above. New subsection under 'Types of solar simulators': 'Flashed solar simulators'edit
This discussion of flashed solar simulators merits its own subsection. Original:
The second type of solar simulator is the flashed or pulsed simulator which is qualitatively similar to flash photography and uses flash tubes. With typical durations of several milliseconds, very high intensities of up to several thousand suns are possible. This type of equipment is often used to prevent unnecessary heat build-up in the device under test. However, due to the rapid heating and cooling of the lamp, the intensity and light spectrum are inherently transient, making repeated reliable testing more technically challenging. Solid-state lamp technology such as LEDs mitigate some of these heating and cooling concerns in flash solar simulators[38]. The solar simulator standards provide guidance for steady-state compared to flashed solar simulators. For example, ASTM E927 section 7.1.6.3 provides guidance on temporal instability measurements for flashed solar simulators[18].
The discussion is long enough to warrant a visible break from other solar simulator discussions in its own subsections. The text about temporal stability of the standards not applying to this type of solar simulator is false as per 7.1.6.3 of ASTM E927 which specifies that for flashed or pulsed simulators "repeat 7.1.6.2 for a minimum of 20 successive pulses" where Section 7.1 specifies test methods for temporal instability of irradiance.
New section: 'Solar simulator construction'edit
This section needs to be added to inform readers of the basic building blocks of a solar simulator, in order to provide better context for subsequent sections where lamp types are discussed.
Changes to 'Types of lamps' sectionedit
Xenon arc lamp: this is the most common type of lamp both for continuous and flashed solar simulators. These lamps offer high intensities and an unfiltered spectrum which matches reasonably well to sunlight. However, the Xe spectrum is also characterized by many undesirable sharp atomic transitional peaks, making the spectrum less desirable for some spectrally sensitive applications. Metal Halide arc lamp: Primarily developed for use in film and television lighting where a high temporal stability and daylight colour match are required, metal halide arc lamps are also used in solar simulation. QTH: quartz tungsten halogen lamps offer spectra which very closely match black body radiation, although typically with a lower color temperature than the sun. LED: light-emitting diodes have recently been used in research laboratories to construct solar simulators, and may offer promise in the future for energy-efficient production of spectrally tailored artificial sunlight. New: Several types of lamps have been used as the light sources within solar simulators. The lamp type is arguably the most important determining factor of a solar simulator’s performance limits with respect to intensity, spectral range, illumination pattern, collimation and temporal stability[1].
There is much more discussion and content needed for each lamp type that merit their own subsections, and putting the lamp types into alphabetical order removes implicit bias from the order the information is presented in.
See in-line citations above. New subsection under 'Types of lamps': 'Argon arc lamps'edit
Original: There is currently no content for this New: Argon arc lamps were used in early solar simulation studies (1972) and have a high color heat emission of 6500 K well-matched to the sun’s blackbody temperature, with a relatively broad spectral emission from 275 nm to 1525 nm[1]. High-pressure argon gas cycles between an anode and a cathode, with a water vortex flowing along the inside quartz tube wall to cool the arc edge[14]. Argon arc lamps carry the disadvantages of short lifetimes and poor reliability[1]. A sample spectrum is included below[39].
This type of solar simulator lamp was absent in the past.
See in-line citations above. New subsection under 'Types of lamps': 'Carbon arc lamps'edit
Original: There is currently no content for this New: Carbon arc lamps have an emission similar to AM0 and are therefore used for solar simulators designed to produce extrasolar spectra (being used for NASA’s first space simulators)[1]. Carbon arc lamps benefit from higher-intensity UV emission. However, they have the disadvantage of being generally weaker in intensity than similar xenon arc lamps [1]. In addition, they have a short lifetime, are unstable during operation and emit high-intensity blue light mismatched to the solar spectrum[1]. An example spectrum is included below[40].
The carbon arc lamp was absent from the previous article.
See in-line citations above. New subsection under 'Types of lamps': 'Light-Emitting Diodes (LEDs)'edit
Original: LED: light-emitting diodes have recently been used in research laboratories to construct solar simulators, and may offer promise in the future for energy-efficient production of spectrally tailored artificial sunlight. New: Since approximately the year 2000, Light-emitting diodes (LEDs) have become commonly used in PV solar simulators[37]. LEDs emit light when electron-hole pairs recombine[41]. They are low-cost and compact with low power consumption[1]. They typically have narrow bandwidths of the order of 10 nm - 100 nm, so multiple LEDs need to be combined to make a solar simulator[42]. As such, the spectral match of a LED solar simulator is largely determined by the number and type of LEDs used in its design. LEDs can be accurately controlled to time windows less than a millisecond for steady or flashed solar simulator applications[1]. Additionally, LEDs have a very long life cycle compared to all other solar simulator lamp types and are very efficient in energy conversion[1]. Ongoing research and development on LEDs is continually driving down their cost[1] and expanding their spectral coverage[42], allowing them to be increasingly employed in wider-spectrum solar simulators. LED solar simulators are unique in that their spectra can be tuned electrically (by increasing or decreasing the intensity of various LEDs) without the need for optical filters[43]. Compared to xenon arc lamps, LEDs have demonstrated equivalent results in IV testing of photovoltaic modules, with better stability, flexibility and spectral match[44]. Because LED emission is somewhat sensitive to junction temperature, they have the disadvantage of requiring adequate thermal management[45]. Two example spectra are included below, showing the capability for low[43] or high[46] spectral match depending on the number and type of LEDs used.
The state of the art of LED solar simulators has changed dramatically, and the current article does not reflect existing research and commercially-available LED solar simulators.
See in-line citations above. New subsection under 'Types of lamps': 'Metal Halide Arc lamps'edit
Original: Metal Halide arc lamp: Primarily developed for use in film and television lighting where a high temporal stability and daylight colour match are required, metal halide arc lamps are also used in solar simulation. New: Metal Halide arc lamps were primarily developed for use in film and television lighting where a high temporal stability and daylight colour match are required. However, for these same properties, metal halide arc lamps are also used in solar simulation. These lamps produce light through a high-intensity discharge (HID) by passing an electric arc through vapourized high-pressure mercury and metal halide compounds[14]. Their disadvantages include high power consumption[1], high electronic driver costs[1], and short life cycles[1]. However, they have the benefit of relatively low costs[14], and because of this low cost, many large-area solar simulators have been built with this technology[47] [48]. An example spectrum is given below[49]
There was much detail absent from the original article on metal halide solar simulator lamps.
See in-line citations above. New subsection under 'Types of lamps': 'Quartz-tungsten Halogen lamps'edit
Original: QTH: quartz tungsten halogen lamps offer spectra which very closely match black body radiation, although typically with a lower color temperature than the sun. New: Quartz-tungsten halogen lamps (QTH lamps) offer spectra which very closely match black body radiation, although typically with a lower color temperature than the sun.They are a type of incandescent lamp where a halogen such as bromine or iodine surrounds a heated tungsten filament[14]. Their disadvantage is that they have a maximum color temperature of 3400 K meaning they produce less UV and more IR emission than sunlight[14]. They are high-intensity[1] and low-cost[1], and are widely used in less spectrum-sensitive applications like concentrated solar collector testing[14]. An example spectrum is included below[50].
There was significant detail absent from the original content.
See in-line citations above. New subsection under 'Types of lamps': 'Supercontinuum laser'edit
Original: There is currently no content for this New: A super continuum laser is a source of high-power, broadband light that can range from the visible range to the IR[1]. Lasers are high-intensity and easy to focus, but have the disadvantage of only illuminating very small areas[1]. Their high intensities, however, allow for testing of photovoltaic modules in solar concentrator applications. An example spectrum is included below[51].
This is a type of solar simulator which needs to be mentioned along with all other lamp types.
See in-line citations above. New subsection under 'Types of lamps': 'Xenon arc lamps'edit
Expansion of discussion of properties, advantages and disadvantages, better schematic drawing, and better spectrum to enable comparison to other lamp types. Original:
Xenon arc lamp: this is the most common type of lamp both for continuous and flashed solar simulators. These lamps offer high intensities and an unfiltered spectrum which matches reasonably well to sunlight. However, the Xe spectrum is also characterized by many undesirable sharp atomic transitional peaks, making the spectrum less desirable for some spectrally sensitive applications. New: Xenon arc lamps are the most common type of lamp both for continuous and flashed solar simulators. They are a type of high-intensity discharge (HID) lamp where light is produced from an electric arc through ionized, high-pressure xenon gas [14]. These lamps offer high intensities and an unfiltered spectrum which matches reasonably well to sunlight. Furthermore, these lamps exhibit no significant spectral balance shift due to differences in power, reducing the need for power source stability[1]. Because they emit high intensities from a single bulb, a collimated high-intensity beam can be produced from xenon arc lamps[14]. However, the xenon arc lamp spectrum is characterized by many undesirable sharp atomic transitional peaks, as well as generally stronger emission in the infrared[14] making the spectrum less desirable for some spectrally sensitive applications. These emission peaks are typically filtered using glass filters[1]. Xenon lamps carry many disadvantages including a high power consumption[1], a need for constant maintenance[1], a short life cycle [1], a high cost[14], an output sensitivity to power supply instabilities[14], a risk of bulb explosion due to their operation via high-pressure gas[14], and an ozone respiratory hazard due to ozone production from UV radiation[14]. A schematic of the components of a typical xenon-arc-lamp solar simulator is given below, along with a typical spectrum[44].
Significant detail was absent from the original content and the quality of the images was very low.
New section: 'List of Solar Simulator Manufacturers'edit
De-clutter the presentation of companies, decouple them from basic information about solar simulators and their operating principles, and update the list of current companies to include latest technological advances.
FreshAlien (talk) 02:37, 16 November 2021 (UTC)
References
(Refactored from Talk:Solar Simulator by Rotideypoc41352 (talk · contribs) at 13:18, 16 November 2021 (UTC)). Add example spectrum for carbon arc lamp solar simulatoredit
An example figure should be added for the carbon arc lamp type: The caption should be as follows: The spectral output of a carbon arc lamp, after passing through an optical filter to achieve better spectral match to AM1.5G[1].
All other solar simulator lamp types have example spectra.
See in-line citation above. FreshAlien (talk) 20:52, 22 November 2021 (UTC) References
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