Introduction
This application note explains a few approaches to creating color consistent LED-based illumination products and guides readers in how to work effectively with Cree products to achieve this goal.
LEDs, as with all semiconductor devices, have material and process variation which yields product with corresponding variation in performance. LEDs are binned and packaged to balance the nature of the manufacturing process with the needs of the lighting industry. Lighting-class LED products are driven by the needs of the solid-state-lighting industry, application requirements and industry standards, including color consistency, as well as color and lumen maintenance.
The need for color consistency in LED illumination
There is nothing like a picture to illustrate the need for every illumination technology to deliver consistent color. It is an example of the problem we are trying to solve.
Figure 1: The need for color consistency spans all illumination technologies.
Though this illustration is from an array of HID lamps illuminating the facade of a building, it shows the undesirable results of inconsistent color in manufacture and color maintenance of luminaires as they age.
An increasingly active industrial policy in the United States, European Union and throughout the world, is resulting in a rigorous set of performance requirements for LED lighting applications. For example, the 2010 document “ENERGY STAR® Program Requirements for Integral LED Lamps”2 proposes stringent requirements, significantly above those for CFLs3, the first industrial policy mandated illumination technology. The LED Lamp requirements were preceded by the 2008 document “ENERGY STAR Program Requirements for Solid State Lighting Luminaires4.” In each of these documents, there are requirements in CCT, CRI, lumen and color maintenance for an Energy Star approved LED illumination product, shown in Tables 1 and 2 below.
Criteria Item
ENERGY STAR Requirements
Reference Standard/Test Method
Sample Size/Specific Requirements
Laboratory Requirements
Correlated Color Temperature (CCT) and Duv
Lamp must have one of the following designated CCTs (per ANSI C78.377-2008) consistent with the 7-step chromaticity quadrangles and Duv tolerances listed below (see Appendix A for more information).
LM-79-08 ANSI C78-377-2008
10 units per model
-5 base-up
-5 base-down
At least 9 out of 10 samples must meet specification
DOE CALiPER Recognized or NVLAP Accredited for LM-79-08
Nominal CCT
Target CCT (K) and tolerance
Target Duv and tolerance
2700 K
2725 ± 145
0.000 ± 0.006
3000 K
3045 ± 175
0.000 ± 0.006
3500 K
3465 ± 245
0.000 ± 0.006
4000 K
3985 ± 275
0.001 ± 0.006
Table 1: Energy Star requirements for Integral LED lamps, per program requirements (V1.1).
Luminaire Requirements
Correlated Color Temperature (CCT)
The luminaire must have one of the following designated CCTs and fall within the 7-step chromaticity quadrangles
Nominal CCT(1)
CCT (K)
2700 K
2725 ± 145
3000 K
3045 ± 175
3500 K
3465 ± 245
4000 K
3985 ± 275
4500 K
4503 ± 243
5000 K
5028 ± 283
5700 K
5665 ± 355
6500 K
6530 ± 510
Table 2: Energy Star requirements for LED Luminaires, per program requirements (V1.1).
These requirements highlight the need to achieve defined, repeatable results with the manufacturing output the LED supplier.
The basic approaches
There are three ways in which a company can work with Cree to procure LEDs to achieve color-consistent lighting products:
- Buy one, or a very small number of bins. The purchase of the same small collection of parts over and over is a reasonable and repeatable strategy, but due to the nature of LED manufacturing this is never the lowest cost way to procure a production supply of LEDs.
- With the release of EasyWhite™ products, beginning in late-2009, Cree has made it possible for its customers to work with LEDs in a way that is similar to original bulb-specification practices, e.g., specifying just CCT and flux. Cree performs color mixing on behalf of its customers in building EasyWhite versions of the XLamp MC-E or MP-L LEDs.
- Traditionally the most cost effective way to work with Cree is to buy full distributions of XLamp LEDs, that is, the full manufacturing output of an LED production run, which includes variety in flux and chromaticity. In order to use full distributions effectively, the customer develops expertise in multi-LED illumination systems and color mixing recipes. Color mixing recipes offer flexible and multiple solutions to create repeatable chromaticity results and can deliver a cost-competitive advantage over the first two approaches.
The rest of this document gives a framework and set of tools for those who want to do color-mixing in their own multi- LED illumination products.
LED binning
LEDs can be characterized in multiple ways. For color mixing, the two most important dimensions are color and flux. These parameters are collected as part of the LED component manufacturing process and are the basis for the component binning discussed in this document.
Chromaticity bins
Cree provides industry leading granularity by defining sub-bins within each of the ANSI C78.377 bins for warm, neutral and cool white XLamp products.
Figure 2: XLamp warm- and neutral-white bins.
Each product family has a binning and labeling document which provides the necessary specification to order Cree LED components.
- Cree® XLamp® XP Family LED Binning and Labeling, CLD-AP22
- Cree® XLamp® MX-6 LED Binning and Labeling, CLD-AP30
- Cree® XLamp® MC-E LED Binning and Labeling, CLD-AP20
Beginning in December 2009, Cree launched a version of a multi-die LED component, the XLamp MC-E EasyWhite™. A second multi-die member of the EasyWhite binning family was announced with launch of the XLamp MP-L EasyWhite. EasyWhite represents a significant simplification of the progression of multiplying LED bins as the map below shows. Instead of dozens of chromaticity bins, there is only one chromaticity bin for each standard color temperature. This approach is also unique in that each of the four bins are centered on the Black Body Line.
Figure 3: EasyWhite bins.
Flux bins
Luminous flux is an additive metric just as perceived color is additive. Many types of luminaires are created by laying out arrays of LEDs and summing the flux of the entire array. Cree XLamp LEDs are also characterized by their luminous flux at a nominal current5. An example of this categorization follows:
K2
30.6
35.2
Q3
93.9
100
K3
35.2
39.8
Q4
100
107
M2
39.8
45.7
Q5
107
114
M3
45.7
51.7
R2
114
122
N2
51.7
56.8
R3
122
130
N3
56.8
62.0
R4
130
139
P2
67.2
73.9
S2
148
156
P3
73.9
80.6
S3
156
164
P4
80.6
87.4
S4
164
172
Q2
87.4
93.9
Table 3: Example Cree flux bins.
Using colorimetry and binning information in illumination specification
In order to understand why multi-LED color mixing is an important and cost effective manufacturing technique, consider the following hypothetical distribution of LEDs in a large production run. No LED manufacturer can produce uniform color points in their white LEDs; rather they produce batches of LEDs with varying distributions of color, and flux and create inventory based on the results of the production.
Figure 4: Hypothetical LED component distribution.
Customers who find ways to use a wider collection of color bins can expect to purchase their LEDs at a lower cost than a customer who will only purchase a particular bin.
These three approaches are illustrated graphically in the following illustrations.
Three approaches buy single (or few) chromaticity bins
Figure 5: Buy single bins - a price-insensitive strategy.
Use Cree EasyWhite parts
Cree EasyWhite LEDs are built using the color mixing techniques described in the next section, offering both excellent color consistency and manufacturing repeatability.
Figure 6: Buy EasyWhite bins, a structurally repeatable strategy.
Do color mixing in the LED system
For some multi-LED applications, mixing white LEDs from a variety of bins is a cost effective way to achieve good color quality while minimizing LED costs. In this Illustration we show four LEDs can achieve the same perceived result as if four LEDs from one of the central subbins were used instead.
Mathematically the results come because color and flux are additive. LEDs are typically characterized by chromaticity (x, y in the 1931 CIE color space) and flux (Φ =Y).
Tristimulus values, used in color mixing math, can be calculated as follows:
The Combined color is the result of the added tristimulus values:
and
Figure 7: Multi-LED luminaires can use color mixing and spend less on LEDs.
Of course, there are caveats having to do with luminaire design. In order to obtain the benefits of color mixing, the fixture must be far enough away from the observer that the LEDs “blend” together. Alternately there must be a set of secondary optics to mix and homogenize an array of LEDs with slightly different hues.
Design example: 2900 K
This example is solved in a number of ways. The goal is a 2900 K luminaire and as close to the Black Body Line as possible. A Cree subbin that satisfies this colorimetric requirement is 7D3. Assuming the luminaire is a multi-LED device, there are multiple other ways to satisfy production requirements.
Solution using two bins
Figure 8: Two XLamp XP-E LEDs warm-white-mixing example.
Properly mixed, results of these two LEDs deliver light that appears to fall in the 7D3 bin and are illustrated graphically below.
Figure 9: Two LEDs to achieve bin 7D3 at 161 lumens.
Similar math can be used to achieve color-mixing results with three and four LEDs as well.
Solution using three bins
Figure 10: Three LEDs to achieve bin 7D3 at 247 lumens.
Solution using four bins
Using color mixing recipes, for every chromaticity target there are multiple ways to utilize the entire production distribution to achieve system results that are color-consistent and cost-effective.
Cree’s color mixing tool, the Binonator
Cree has developed a software tool to automate color and flux math and display resulting output over Cree’s entire defined XLamp color binning space.6
The Binonator is a Microsoft Windows application, and requires a local copy of Microsoft Excel for correct execution. It is available for controlled-access download from the Cree website. In addition to Excel, the binonator requires the Microsoft .NET 4.0 framework for operation. The downloaded file is a self-extracting executable file that installs application and configuration files on a target computer.
Figure 11: Four LEDs to Achieve Bin 7D3 at 322 Lumens.
Contact your Cree sales representative to get access to Binonator download information.
The tool allows users to:
- Specify and visualize an N-step MacAdam ellipse around a series of Correlated Color Temperatures, centered on the Black Body Line.
- Specify a series of LEDs each with associated color and flux bins.
- Calculate the resulting flux and color point.
- Display a graphical result of items one through three above.
- Read and write recipe files to retrieve and store the recipe data.
The tool uses the following assumptions:
- The color point of any LED in any particular color bin is the average or center of the bin.
- The flux of the LED is the minimum flux of the selected flux bin.
Any of Cree’s 104 XLamp color bins can be used to create results, but there are practical limits to using widely spaced and non-adjacent color bins, which are application, implementation and viewer-dependent. For example, street lighting – where the luminaire can be 10 meters (30 feet) above the illuminated surfaces and the illumination source is very bright relative to ambient – is a lighting application that is quite forgiving of color mixing with a variety of non-adjacent color bins. While a non-diffused indoor application, such as an LED-based T8 lighting tube, may exhibit perceptible color variation when non-adjacent color bins are used side by side. After initial recipes are derived, it is important to test the results before committing to production.
The application is organized into graphical display of the unit (x,y) color space, a status message box (lower left-hand side), settings for Target CCT and number of MacAdam Steps (bottom of display, mid-section), and the calculated results (lower right side).
Select any chromaticity bin by “right-clicking” in the parallelogram that defines the bin. This will cause a menu to display which has a pair of input values for the selected bin. The drop down menu to the left is the union of all flux XLamp flux bins associated with a particular color bin. The cell on the right accepts an integer number of LEDs associated with the bin. Left click the “Submit” button to select the values. The resulting bin will change color to denote the non-zero values associated with the bin. In figure 12, above, we recreate the manual results of Figure 11.
Figure 12: Binonator input screen.
The resultant chromaticity point is displayed, and the coordinates and flux results are presented in the bottom right hand corner of the display.
Figure 13: Binonator input details – rightclicking a bin for data input.
Controls for the display of a target CCT and a N-step MacAdam Ellipse are at the bottom of the display. These are a pair of drop down menus to display a target Correlated Color Temperature and N-step MacAdam ellipse centered about the CCT. These items allow for the graphical display of a target constraint for the color mixing exercise.
Figure 14: Close-up of CCT, MacAdam and non-graphical results.
Finally, color mixing recipes can be saved to a file and read in to the binonator by clicking on the File dialog.
Figure 15: The File Dialog - Reading and Writing Color Mixing Recipes.
The collection of LEDs and their chromaticity and flux bins are called a recipe and are stored in a file with the .cbr (Cree binonator recipe) extension. The Binonator allows for recipes to be written to a file for storage and subsequent retrieval. The files are organized in an XML-based schema.
Conclusions
Mixing is an effective technique to achieve consistent, repeatable multi- LED luminaires. With the Binonator mixing software, Cree has provided a tool to assist our customers in creating chromaticity bin mixing recipes for their LED illumination products.
For any desired color point in the ANSI bin color space, there are large numbers of solutions to utilize Cree’s full distribution, achieve the best possible LED unit costs and deliver consistent color point results.
Bulb and luminaire designers will want to take care to develop appropriate methods to obscure the color variations across an array of LEDs. In the case of cool white LEDs in very bright applications, such as streetlights, almost no special consideration for mixing optics is required. The distance of the source from the viewers combined with the human visual system’s reduced sensitivity to blue spectrum makes for an easy mixing result. Arrays of warm-white LEDs require more care to make sure an appropriate level of in-luminaire mixing occurs so as to obscure the contributions of each LED.
Figure 16: Example .cbr File Format (XML).
- Picture: Taken from “The Roof,” The Wit Hotel, Chicago (Courtesy of Osram).
- http://www.energystar.gov/ia/partners/manuf_res/downloads/IntegralLampsFINAL.pdf.
- See http://www.energystar.gov/ia/partners/prod_development/revisions/downloads/cfls/CriteriaCFLs_V4.pdf.
- http://www.energystar.gov/ia/partners/product_specs/program_reqs/SSL_prog_req_V1.1.pdf.
- Most often 350 mA.
- Contact your Cree sales representative to obtain a copy of the Binonator.
