。IES_LM-79,LM-80

IESApproved Method: Electrical andPhotometric Measurements of Solid-State LightingProductsIES LM-79-08Copyright 2008 by the Illuminating Engineering Society.Approved by the IES Board of Directors December 31, 2007, as a T ransaction of the Illuminating Engineering Society.All rights reserved. No part of this publication may be reproduced in any form, in any electronic retrieval system or otherwise, without prior written permission of the IES.Published by the Illuminating Engineering Society, 120 Wall Street, New Y ork, New Y ork 10005.IES Standards and Guides are developed through committee consensus and produced by the IES Office in New Y ork. Careful attention is given to style and accuracy. If any errors are noted in this document, please forward them to Rita Harrold, Director Educational and T echnical Development, at the above address for verification and correction. The IES welcomes and urges feedback and comments.ISBN # 978-0-87995-226-6Printed in the United States of America.IES LM-79-08 Prepared by the Subcommittee on Solid-State Lighting of the IES Testing Procedures Committee Solid-State Lighting SubcommitteeKevin Dowling, ChairY oshi Ohno, T echnical CoordinatorR. C. BergerR. S. Bergman E. Bretschneider* J. R. CyreM. T. Dyble LC* S. D. Ellersick* D. Ellis*M. GratherP. J. Havens* A. Jackson*J. Jiao*C. F. Jones*M. A. Kalkas* D. Karambelas H. S. Kashani*P. F. Keebler* M. Kotrebai K. K. Krueger J. P. Marella M. J. Mayer D. M. Mesh* C. C. Miller Y. OhnoM. L. Riebling* M. B. Sapcoe* L. Stafford* G. Trott*R. C. Tuttle J. W. Y on * J. X. ZhangC. K. AndersenD. V. Andreyev* J. B. ArensL. M. Ayers W.E. Beakes R. C. Berger R. P. Bergin* R. S. Bergman J. R. Cyre*R. C. Dahl*R. O. Daubach* K. J. Dowling D. EllisA.M. Foy*P. J. Franck* R. V. Heinisch T. T. Hernandez* R. E. Horan D. E. Husby** J. Hospodarsky* J. Jiao*M. A. Kalkas D. Karambelas M. KotrebaiK.K. Krueger B. Kuebler*E. Ladouceur*J. Lawton*L. E. Leetzow*K. C. Lerbs*R. E. Levin*I. LewinR. Low*J. P. MarellaG. McKeeS. W. McKnight*D. C. Mertz**C. C. MillerB. MosherW. A. NewlandY. Ohno*D. W. Parkansky* D. N. RandolphD. RectorM. B. SapcoeD. C. Smith*R. C. Speck**L. Stafford*G. A. SteinbergN. Stuffer**T. G. Y ahraus*J. X. Zhang* Advisory Member ** Honorary MemberIES Testing Procedures CommitteeMichael Grather, ChairThis approved method has been developed in collaboration with the ANSI Solid State Lighting Joint Working Group C78-09 and C82-04.Special recognition to Yoshi Ohno for his technical assistance, review and collaboration.IES LM-79-08Contents1.0 Introduction (1)1.1 Scope (1)1.2 General (1)1.3 Nomenclature and Definitions (1)2.0 Ambient Conditions (2)2.1 General (2)2.2 Air Temperature (2)2.3 Thermal Conditions for Mounting SSL Products. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22.4 Air Movement (2)3.0 Power Supply Characteristics (2)3.1 Waveshape of AC power supply (2)3.2 Voltage Regulation (2)4.0 Seasoning of SSL Product. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35.0 Stabilization of SSL Product (3)6.0 Operating Orientation (3)7.0 Electrical Settings (3)8.0 Electrical Instrumentation (3)8.1 Circuits (3)8.2 Uncertainties (3)9.0 Test Methods for Total Luminous Flux measurement (4)9.1 Integrating sphere with a spectroradiometer (Sphere-spectroradiometer system) (4)9.1.1 Integrating sphere (4)9.1.2 Sphere geometry (5)9.1.3 Principle of measurement (6)9.1.4 Spectroradiometer (7)9.1.5 Self-absorption correction (7)9.1.6 Calibration (7)9.2 Integrating sphere with a photometer head (Sphere-photometer system) (7)9.2.1 Integrating sphere (7)9.2.2 Sphere geometry (7)9.2.3 Principle of measurement (8)9.2.4 Photometer head (8)9.2.5 Self-absorption correction (8)9.2.6 Determination of f'1, and Spectral Mismatch Correction Factor (9)9.2.7 Calibration (9)9.3 Goniophotometer (9)9.3.1 T ype of Goniometer (9)9.3.2 Principle of T otal Luminous Flux Measurement (9)9.3.3 Scanning resolution (10)9.3.4 Angle coverage (10)9.3.5 Polarization (10)9.3.6 Photometer head (10)9.3.7 Calibration (10)10.0 Luminous Intensity Distribution (10)11.0 Luminous Efficacy (11)IES LM-79-08 12.0 Test Methods for Color Characteristics of SSL Products (11)12.1 Method using a sphere-spectroradiometer system (11)12.2 Method using a spectroradiometer or colorimeter spatially scanned (11)12.3 Spectroradiometer parameters impacting measured color characteristics (12)12.4 Colorimetric calculations (12)12.5 Spatial non-uniformity of chromaticity (12)13.0 Uncertainty statement (13)14.0 Test Report (13)References (14)Annex (Informative). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15IES LM-79-08IES LM-79-081IES LM-79-082IES LM-79-083IES LM-79-084IES LM-79-08for this purpose. The auxiliary lamp light output needs to be stable throughout all of the self-absorp-tion measurements.An interior coating reflectance of 90 % to 98 % is recommended for the sphere wall, depending on the sphere size and usage of the sphere. A higher reflec-tance is advantageous for higher signal obtained, and smaller errors associated with spatial nonuni-formity of sphere response and intensity distribution variations of the SSL products measured. Higher reflectance is preferred particularly for a sphere-spectroradiometer system to ensure sufficient signal-to-noise ratios in the entire visible region. It should be noted, however, that, with higher reflectance, the sphere responsivity becomes more sensitive to self-absorption effects and long-term drift, and also, there will be more variation in spectral throughput. If there is an opening in the sphere, the average reflectance should be considered, and higher coat-ing reflectance will be advantageous to compensate for the decrease of average reflectance.9.1.2 Sphere geometry Figure 1shows recom-mended sphere geometries of a sphere-spectroradi-ometer system for total luminous flux measurement of SSL products. The reference standards are for total spectral radiant flux. The 4p geometry (a) is recommended for all types of SSL products includ-ing those emitting light in all directions (4p sr) or only in a forward direction (regardless of orientation). The 2p geometry (b) is acceptable for SSL products emitting light only in forward directions (regardless of orientation), and may be used for SSL products having a large housing or fixture that are too large to use the 4p geometry. In either geometry, the size of the SSL product under test should be limited for a given size of the sphere to ensure sufficient spatial uniformity of light integration and accurate correction for self-absorption. For measurement of integrated LED lamps, the sphere may be equipped with a lamp holder with a screw-base socket.In the 4p geometry, as a guideline, the total surface area of the SSL product should be less than 2 % of the total area of the sphere wall. This corresponds to, for example, a spherical object of less than 30 cm diameter in a 2 m integrating sphere. The longest physical dimension of a linear product should be less than 2/3 of the diameter of the sphere.In the 2p geometry, the opening diameter to mount a SSL product should be less than 1/3 of the diameter of the sphere. The SSL product shall be mounted within the circular opening and in such a way that its front edges are flush with the edges of the open-ing (or it can be slightly inside the sphere to ensure that all emitted light is caught in the sphere). In this case, the gaps between the edges of the opening and the SSL product (or reference standard) can be covered with a surface (inner side is white) in order that the measurement can be made in a room with normal ambient lighting as the sphere is completely shielded from outside (See Figure 2(a)). If this is not convenient and the gaps are to be kept open, a dark room arrangement (around the opening, at least) may be necessary so that no external light or reflected light enters the sphere (See Figure 2 (b)). In either case, the SSL product under test should be mounted to the sphere so that support material or structure does not conduct the heat from the SSL product to the sphere wall. See also section 2.3.In either geometry, the size of the baffle should be as small as possible to shield the detector port from direct illumination from the largest test SSL product to be measured or the standard lamp. It is recom-mended that the baffle is located at 1/3 to 1/2 ofFigure 1. Recommended sphere geometries for total luminous flux measurement using a spectroradiometer. (a): for all types of SSL products, (b): for SSL products having only forward emission.(a) 4p geometry (b) 2p geometry56IES LM-79-08the radius of the sphere from the detector port. The auxiliary lamp should have a shield so that its direct light does not hit any parts of the SSL product under test or the detector port.Standard lamps for total spectral radiant flux are normally quartz-halogen incandescent lamps that have broadband spectrum to calibrate the spectro-radiometer for the entire visible region. For the 2p geometry, standard lamps having only forward distri-butions are required. For example, a quartz-halogen lamp with a reflector providing appropriate intensity distributions may be used as a reference standard source. For the 4p geometry, standard lamps having omni-directional intensity distributions are commonly used but standard lamps having forward intensity distributions may also be needed. Note that the light output of incandescent standard lamps changes if their burning position is changed.It should be noted that integrating spheres do not have perfectly uniform responsivity over their internal sphere surfaces. The sphere responsivity tends to be slightly lower for the lower half of the sphere due to contamination by falling dust, and also around the sphere seams where small gaps exist. Therefore, if a sphere (4p geometry) is calibrated with an omni-directional standard lamp and measures an SSL product having downward intensity distributions, the luminous flux tends to be measured slightly lower than it is. This error tends to be more prominent for light sources having narrow beam distributions. The magnitude of errors depends on how well the sphere is designed and maintained, and will be cancelled if the angular intensity distributions of the standard lamp and the test SSL products are the same. T o ensure that this error is not significant, standard lamps having different intensity distributions (omni-direction, downward/broad, downward/narrow) may be prepared and chosen for the type of SSL prod-ucts to be measured. Or, if only omni-directional standard lamps are used, correction factors should be established and applied when SSL products hav-ing different intensity distributions are measured. Such correction factors may be established by measuring lamps or SSL products having different intensity distributions calibrated for total luminous flux using other accurate means (e.g., calibration traceable to national measurement institute (NMI), or using well-designed goniophotometer).The ambient temperature in a sphere shall be moni-tored according to section 2.2. A temperature probe is often mounted behind the baffle that shields the detector port from the light source if the baffle is mounted at the same height as the center of the sphere (case of Figure 1 (a)). When a SSL product is mounted on the sphere wall (e.g., case of Figure 1 (b)), the ambient temperature shall be measured behind the baffle (side of spectroradiometer) in the sphere, in addition to the ambient air outside the sphere near the product (follow section 2.2). Both readings must meet the 25±1°C requirement. If the ambient temperature in the closed sphere exceeds 25±1°C due to the heat generated by the SSL product under test, the SSL product may be stabilized with the sphere partially open to achieve the required ambient temperature within 25±1°C until measure-ment is made with the sphere closed. When measure-ment is taken, the sphere should be closed gently to avoid air movement inside the sphere. Note that, if the stability of the flux output of the product is monitored with the sphere photometer when the sphere is open, the room lights should be turned off and the position of open hemispheres should not be moved.9.1.3 Principle of measurement The instrument (integrating sphere plus spectroradiometer) must be calibrated against a reference standard calibrated for total spectral radiant flux. Since the integrating sphere is included in this calibration, the spectral throughput of the sphere need not be known. The total spectral radiant flux U TEST (m ) of a SSL product under test is obtained by comparison to that of a reference standard U REF (m ):Figure 2. Mounting conditions of the SSL product under test.IES LM-79-0878IES LM-79-08(a) 4p geometry (b) 2p geometryFigure 3. Recommended sphere geometries for total luminous flux measurement using a photometer head. (a): for all types of SSL products, (b): for SSL products having only forward emission.IES LM-7 -08IES LM-79-0810IES LM-79-081112IES LM-79-08The chromaticity coordinates and luminous intensity for z =0° and z =90° (or more z angles) are first aver-aged at each i angle and expressed as x (i i ), y (and I (i i ) where i i =0°, 10°, 20°,…., 180°. Then the average chromaticity coordinate x a is calculated as a weighted mean:=19∑i =1x (i i )•w i (i i ) with w i (i i )= I (i i )•X (i i )19∑i =1I (i i )•X (i i )(13)and2p [cos(i i ) - cos (i i + D i2 )]; for i i =0º(i i )={2p [cos(i i- D i 2 )-cos(i i+ D i2 )] ; f or i i=10º, 20º, ...170º2p [cos(i - D i) - cos(i )] ; f or i =180ºFigure 4. Geometry for the chromaticity measurement using a goniometer (the figure shows the case for a SSL product emitting light in downward directions only).IES LM-79-0813IES LM-79-08References1. IESNA Light Sources Committee, IESNATechnical Memorandum on Light Emitting Diode (LED) Sources and Systems, TM-16-05.2. Commission Internationale de l'Eclairage,Photometry – The CIE System of Physical Photometry, CIE S010/E:2004 / ISO 23539-2005(E).3. Commission Internationale de l'Eclairage,Colorimetry, 3rd edition, CIE 15:2004.4. ANSI, Specifications of the Chromaticity of SolidState Lighting Products, ANSI-NEMA-ANSLG C78-09.377-2008.5. ISO, Guide to the Expression of Uncertainty inMeasurement, 1st Edition, 1993.6. ANSI, U.S. Guide to the Expression of Uncertaintyin Measurement, ANSI/NCSL Z540-2-1997.7. IESNA Testing Procedures Committee, IESNAApproved Method for Total Luminous Flux Measurement of Lamps Using an Integrating Sphere Photometer, LM-78-2007.8. Commission Internationale de l'Eclairage,Measurement of Luminous Flux, CIE 84:1989.9. IESNA Testing Procedures Committee,Goniophotometer Types and Photometric Coordinates, LM-75-01.10. Commission Internationale de l'Eclairage,Methods of Characterizing Illuminance Meters and Luminance Meters, CIE 69:1987.11. IESNA Testing Procedures Committee, I ESNAApproved Method for Photometric Testing of Indoor Fluorescent Luminaires, LM-41-98.12. IESNA Testing Procedures Committee,Photometric Testing of Outdoor Fluorescent Luminaires, LM-10-96. 13. IESNA Testing Procedures Committee,Photometric Testing of Searchlights, LM-11-97.14. IESNA Testing Procedures Committee,Photometric Testing of Reflector Type Lamps, LM-20-94.15. IESNA Testing Procedures Committee,Photometric Testing of Roadway Luminaires Using Incandescent Filament and HID lamps, LM-31-95.16. IESNA Testing Procedures Committee, ApprovedMethod for Photometric Testing of Floodlights Using High Intensity Discharge or Incandescent Filament Lamps, LM-35-02.17. IESNA Testing Procedures Committee,Photometric Testing of Indoor Luminaires Using HID or Incandescent Filament Lamps, LM-46-04.18. IESNA Testing Procedures Committee,Standard File Format for the Electronic Transfer of Photometric Data and Related Information, LM-63-02.19. Commission Internationale de l'Eclairage,International Lighting Vocabulary, CIE 17.4-1987/ International Electrotechnical Commission, Publication 50 (845)-1989.20. IESNA Testing Procedures Committee, IESNAGuide to Spectroradiometric Measurements, LM-58-94.21. Commission Internationale de l'Eclairage,Spectroradiometric Measurement of Light Sources, CIE 63-1984.22. Ohno, Y., Chapter 5 Spectral ColourMeasurement, Colorimetry—Understanding the CIE System, edited by J. Schanda, John Wiley & Sons, Inc., Hoboken New Jersey, 2007.23. Commission Internationale de l'Eclairage,Method of Measuring and Specifying Colour Rendering of Light Sources, CIE 13.3-1995.14IES LM-79-08Annex (Informative)This annex provides background information regard-ing the development of this standard. This annex explains how the measurement of solid-state light-ing (SSL) products differ from measurement of tra-ditional lamps and luminaires, why this standard is needed, and why sampling is not addressed.Why Solid-State Lighting is DifferentIn photometric measurements of traditional lamps and luminaires, the operating conditions are differ-ent depending on the type of lamp. These operating conditions include the reference ballast, electrical measurement, stabilization time, handling of lamp, and more. Thus different standards were developed for different lamp types and even luminaires that use multiple lamp types. Standards for measurement of SSL products are needed because LED sources have different requirements for operation and tem-perature conditions than traditional light sources. SSL products can be in the form of lamps such as integrated LED lamps, or luminaires, which range in scale from small lamps to the size of large fluores-cent luminaires. Depending on the size and quanti-ties needed, these products may be measured in an integrating sphere or a goniophotometer. Thus SSL products are measured by lamp photometry engi-neers as well as by luminaire photometry engineers, having different practices and culture. This standard brings a common basis and uniform measurement methods for both groups of engineers. Traditionally, photometric measurements have been made for lamps and for luminaires separately using different test methods. Lamps are typically mea-sured with integrating spheres, and total luminous flux and chromaticity are the main quantities of interest. Luminaires are normally measured with goniophotometers, and luminous intensity distribu-tion and luminaire efficiency are the main quanti-ties of interest. Standards have been developed separately for measurement of lamps (such as LM-9 linear fluorescent lamps, LM-45 incandescent lamps, and LM-66 for compact fluorescent lamps) and for measurement of luminaires (such as LM-41 for indoor fluorescent luminaires). However, for most current SSL products, LED lamps cannot be sepa-rated from luminaires, and the nature of SSL prod-ucts resembles both light sources and luminaires. Thus, none of the existing standards for lamps or luminaires are directly applicable to SSL products. Relative and Absolute PhotometryT raditional luminaire photometry methods do not work for SSL products because traditionally, luminaires are normally tested with a goniophotometer using a procedure called relative photometry. In this method, a luminaire under test and the bare lamp(s) used in the luminaire are measured separately. Then the luminous intensity distribution data of the luminaire measured with the goniophotometer are normalized by the measured total luminous flux of lamps used in the tested luminaire. Therefore, the luminous inten-sity distribution is normally presented in relative scale (e.g., candela per 1000 lumens). Such test methods cannot be used for SSL products because, in most SSL products, LED lamp sources are not designed to be separated from the luminaire. Even if the LED source can be separated and measured separately, the relative photometry method will not work accu-rately because the light output of the LED source will change significantly if operated outside the luminaire due to differences in thermal conditions. Therefore, existing standards for measurement of luminaires cannot be used for SSL products.Some IES standards (e.g., LM-35-02) describe the absolute photometry method, in which the absolute luminous intensity distribution of a lumi-naire is measured without separate measurement of the lamps. SSL products should be measured using such absolute photometry method. However, absolute photometry is rarely used for traditional luminaires and is not described in sufficient detail in these standards. Section 9.3of this standard describes detailed requirements for such absolute photometry for total luminous flux measurement of SSL products.SamplingWith the relative photometry method commonly used for luminaires, the results are independent from individual variations of lamp lumen output because of the normalization using the measured total luminous flux of lamps. As a result, the indi-vidual variation of lamp light output due to lamp variation and variation in the ballast factor of the control gear is removed.Inconsistencies in luminous flux measurements as a result of variations in luminaire geometry are normally insignificant when the inconsistencies due to variations in the luminous flux produced by the lamp(s) are removed. It should be noted that the variation in luminous flux provided by the lamp is a function of both the lamp(s) and their ballast/ control gear. As a result, it has been historically sufficient to measure only one sample for rating a luminaire product. This is the practice often used in performance rating of luminaires. On the other hand, the results of measurement of SSL products are directly affected by the output of the sources, and are always subject to individual variations of LED sources, which tend to be significantly larger15IES LM-79-08than even those of fluorescent lamps. Therefore, measurement of one sample is insufficient for rating SSL products and appropriate sampling and averaging of results is required for SSL products. The tolerance requirements for individual product variations may be different for different applications. LM-79 describes test methods for individual SSL products and does not cover such sampling methods for rating products, which should be covered by a regulatory requirement, customer requirement or agency requirement. Next StepsThis standard will continue to evolve as the SSL industry evolves. In particular, measurement of luminaire characteristics using goniophotometry will need to be further detailed. Requirements of luminaires differ for different lighting applications, and it will require substantial efforts to cover this area. The IES Testing Procedures Committee will continue work to improve this standard as well as develop additional standards and methods needed for measurement of SSL products.16。

LM80测试报告的要求说明一、LM80测试报告的目的二、测试项目1.LED芯片的光通量衰减测试：测试LED产品在规定时间内的光通量衰减情况，比较测试前后的光通量数据，计算光通量衰减率。

2.温度测量：测量LED产品的表面温度、周围环境温度和接触材料的温度，以了解产品在正常工作条件下的温度情况。

3.电流和电压测量：测量LED产品的工作电流和电压，确保产品在额定电流和电压范围内正常工作。

4.光衰测量：测试LED产品在规定时间内的光衰情况，测量其初始光通量和测试后的光通量，计算光衰率。

5.寿命测试：通过对LED产品进行加速寿命测试，模拟长时间使用的情况，以评估产品的可靠性和寿命。

三、测试方法1.LM80测试要使用符合国际电工委员会（IEC）或美国照明工程学会（IES）的标准测试方法。

2.测试设备要符合国际标准，并保持校准状态，确保测试数据的准确性和可信度。

3.测试需在恒定的温度环境和电流条件下进行，以确保测试结果的可比性。

四、测试报告的内容1.产品信息：包括产品型号、生产日期、生产厂商等信息。

2.测试环境：包括测试设备、温度条件、电流和电压设置等信息。

3.测试结果：包括光通量衰减率、光衰率、温度测试结果、电流和电压数据等详细结果。

4.比较分析：将测试数据与产品规格进行比较和分析，评估产品的性能和质量。

5.结论和建议：根据测试结果，对LED产品的寿命和性能做出结论，并提出相关的改进建议。

六、报告的准确性和可靠性1.LM80测试报告应由经过相关培训和资质认证的测试人员进行，确保测试过程的准确性和可靠性。

2.测试报告应尽可能提供详尽的测试数据和结果，并保持数据的真实和可验证性。

3.如果有其他相关测试报告或认证报告，应将其与LM80测试报告一并提供，以进一步验证产品的可靠性和性能。

LED能源之星标准LM79与LM80的区别LM-79:主要测试为光电性能测试，由于某些测试项目需要借助分布式光度计才能完成，所以一般的厂家没有能力做一份完整的报告，这个测试一般针对的是整灯的厂家。

主要的测试项目如下：总光通量:发光效率:光强分布:相关色温（CCT）:显色指数（CRI）:色品坐标（或称色度坐标）:输入交流（或直流）电压:输入交流（或直流）电流:输入功率（DC或AC）:输入电压频率:功率因子:LM-80主要测的是LED光源的流明维持，这一测试针对的是光源厂家，所以生产灯具的厂家只需要向你们的光源厂家要这一份测试报告就好了。

LM-79是固态照明产品电气和光度测量的方法针对所有LED产品的测试方法，包含测试内容：1、电参数（功率、电压、电流、功率因数）2、颜色参数3、光通量、光效4、光强分布5、色度不均匀性LM-79和LM-80与能源之星的关系：LM-79：能源之星中有大量光色参数的要求，其测试方法均引用LM-79作为测试方法标准LM-80：LM-80是针对LED光源光通维持率的测试方法针对LED光源而非LED灯泡和灯具，包含测试内容：1、光源在不同温度下的光通维持率2、光源在不同温度下的色度维持率LM-80的测试数据作为成品光源光通量的引用数据以计算成品灯的光通维持率和色度维持率并非有了LM-80数据就不需做光通维持率，同样需要测试验证。

LM79是IESNA(北美照明工程学会)批准的灯具能效标准。

而LM80光通维持率(LED寿命)标准. IES LM79测试是指固态照明产品的光电测量，主要是测试产品的光通量，光强，颜色度等等。

而IES LM80是LED光源流明维持测试，主要测试的是光通量输出的维持率，也就是LED光源的的寿命测试。

注：光通量是指光源表面辐射出能被人眼视觉感知的光能量。

其计算单位是流明（lm）。

LM79标准的适用范围及简介1. 范围本标准规定了标准条件下进行总光通量、电功率、光强分布、色品的可重现性测量的程序和要遵守的预防措施。

标准含盖了LED的带有电子控制装置和热沉的SSL产品，这些装置要求仅用交流或直流驱动。

本标准不含盖要求有外部驱动电路或外部热沉的SSL产品。

（例如，LED芯片，LED插件和LED模块）。

本标准含盖的SSL产品形式是灯具（含有光源的器具）以及一体化LED灯。

本标准不包括设计不含有光源的SSL产品为销售。

本标准描述了个体间SSL产品的测试方法，不适用于确定个体间产品性能的差异。

1.2 简介本标准定义的SSL产品利用了LEDs (包括无机和有机LEDs)光辐射光源转产生照明光的目的。

当斜线向前方向时，LED是发射非相干光辐射的p-n结半导体装置。

光由用两种方法产生：混合LEDs产生了两种以上的明显光谱，或从应用LEDs的发射（在蓝色区或紫外线辐射区）刺激一种或多种磷在可见区产生宽带发射。

尽管恒流控制是孤立LEDs的象征，本标准涉及了一体化SSL 产品结合半导体装置水平的直流控制，因此有利的电气参数是SSL产品的输入电气参数。

对于特殊用途，当他们在除了本标准描述的标准条件下工作时，它可以有用地确定SSL产品的特性。

这里所做的结果仅对于在他们所获得的特殊条件下或测试报告中规定的这些条件有意义。

SSL产品要求的代表性光度计信息是总光通量（lm），发光效率（lm/W），在一个或多个方向的发光强度（cd）, 色品坐标，相关色温和显色指数。

关于本批准方法的目的，这些数据的确定将考虑光度测量。

测量交流-功能SSL产品的电气特性是输入RMS交流电压，输入RMS交流电流，输入交流功率，输入电压频率和功率系数。

对于直流-功能SSL产品，测量的电气特性是输入直流电压，输入直流电流和输入功率。

关于本批准方法的目的，这些数据的确定可以考虑电气测量。

美国LM79和LM80测试区别IES LM-79-08《固态照明产品电气和光度测量》规定了测量固态照明产品（SSL）的总光通量、电功率、光通强度分布和色度时，所应遵守的程序和注意事项。

LM-79重点提出了SSL产品的总光通量的测量，指出SSL产品的总光通量应使用积分球系统或测角光度计进行测量。

本文主要对积分球系统中所使用的积分球的一些规范进行介绍。

积分球系统适合整体式LED灯以及相对小尺寸的LED灯具的总光通量和色彩特性的测量。

积分球系统具有测量速度快和无需暗室等优点。

使用的积分球系统有两种，一种采用的是校正的光度探头；另一种采用光谱辐射仪作为探测器。

第一种方法容易产生光谱非匹配误差，因此第二种方法更常使用。

在使用积分球配光谱辐射仪进行SSL产品总光通测量中，积分球应该符合一定要求，才能尽可能提高测试的精准度。

首先，积分球的尺寸必须足够大，确保挡板和待测SSL的自吸收造成的测量误差不会太显著。

通常，1米或更大的积分球用来测量紧凑型灯（典型的白炽灯和紧凑型荧光灯）；1.5米或更大型的积分球用来测量尺寸更大的灯具（例如线型荧光灯和HID灯）。

球体尺寸也必须足够大以避免光源散热导致的温度升高。

2米或更大的球通常用来测量500瓦或更大的光源。

积分球必须安装辅助灯以用于自吸收测量。

积分球-光谱辐射仪系统中使用的辅助灯通常为石英卤素灯。

在整个自吸收测量中，辅助灯的光输必须稳定。

球体内壁的反射系数建议为90 %到98 %。

标准推荐的积分球有两种：4π球体和2π球体（见下图）。

4π球体推荐用于所有类型SSL产品，包括那些在所有方向发光的SSL以及只朝固定方向发光的SSL。

2π球体主要用于只朝固定方向发光的SSL，同时也可能使用于具有较大的外罩或支座，不能用4π球体进行测量的固态照明产品。

不管使用哪种球体，待测的SSL产品的尺寸应该限制在一定范围内，以确保对自吸收的准确校正。

对于测量整体式led灯，积分球应安装带有螺纹插座的灯头。

lm79标准测试方法和要求
LM79标准测试方法和要求是关于LED照明产品性能测试的
一项国际标准。

根据美国能源部、国家电力委员会(National Electrical Manufacturers Association，简称NEMA)和美国照明
工程学会（Illuminating Engineering Society of North America，
简称IESNA）共同制定的标准。

以下是LM79标准测试方法和要求的主要内容：
1. 测试目的：评估LED光源性能，包括亮度、光通量、光电
效率等关键参数。

2. 测试项目：包括电源输入特性、光电参数、光照分布、光谱分布、色度参数、色温等多个项目。

3. 测试装置：要求使用经过校准和认证的测试设备，如标准光度计、照度计、光谱辐射计等。

4. 测试条件：在特定的环境条件下进行测试，包括温度、湿度、环境照度等。

5. 测试程序：按照规定的步骤进行测试，包括灯光预热、测量前准备、数据采集等。

6. 测试结果：将测量得到的数据进行计算、分析和报告，最终得出产品的性能评估。

7. 测试报告：要求按规定的格式输出测试结果和相关数据，并提供相关的图表和说明。

总结来说，LM79标准测试方法和要求是为了保证LED照明
产品的性能和质量一致性，提供了规范的测试流程和指标要求。

通过进行LM79标准测试，可以评估LED光源的亮度、光通量、光电效率等关键参数，为产品设计和使用提供科学依据。

LM-80标准有关定义说明
1、测量仪器
电子测量仪器是电压表、电流表和功率表。

温度的单位是摄氏度，光度的单位是流明。

2、LED 光源
LED包，阵列，或通过辅助驱动器操作的模型。

3、流明维持
流明维持是保持的输出在任一选定的实际时间里输出的光通量（通常以最大输出量的百分数表示）。

流明维护与流明降落是相反的。

4、流明维护寿命
指定的流明降落或流明维护百分数达到的时间，用小时表示。

操作时间不包括灯源重复打开或关闭以及周期性打开的实际时间。

5、 LED 光源故障
无法发光等故障，如生产缺陷引起的过早故障进行报道，但
是不包含在 LED光源流明维护计算中。

6、额定流明维护寿命(L
p
)
LED光源的实际操作时间将保持为起始光输出的百分数，如°
L 70(小时): 时间70% 流明维护 ° L
50
(小时): 时间50% 流明维护 °
L
50
(小时):
7、壳体温度(T
s
)
Ts是厂家包装中规定的，LED光源包装上热电偶安装点的温度。

IES LM-79:2008标准简介近期越来越多的美国买家要求LED灯具出具LM-79的测试报告，这一块也慢慢越来越受各个LED 生产厂家的关注。

因为一般厂家的积分球满足不了该标准的测试要求，有一部分的项目需要借助分布式光度计才能完成，而一份完整的LM-79测试报告这些测试项目也都有要求，因此将此标准的简单介绍写下来，以供大家探讨。

IES LM-79-08标准内容简介：IES LM-79-08《固态照明产品电气和光度测量》规定了测量固态照明产品(SSL)的总光通量、电功率、光通强度分布和色度时，所应遵守的程序和注意事项。

标准适用于基于LED的、集成了控制电路和散热槽、因此只需要交流或直流电源便可运行的SSL产品;不适用于需要外部运行电路或外部散热槽(如LED芯片、LED封装、LED模块等)的SSL产品。

标准的第2到第8章介绍了产品在测量时的各种要求。

在测量时，环境温度和空气流动对于测量结果影响较大。

测量时的环境温度应保持在25℃±1℃，温度传感器应与SSL产品同高度，距离不超过1米，并避免受到SSL产品和其他光源的直接照射。

SSL产品的支撑装置应采用热传导性较差的材料(如聚四氟乙烯)。

测量装置内的空气流动应足够小，以免影响到装置所产生的正常的空气对流。

测量时还应当注意SSL产品的老化和稳定问题。

在对新的SSL产品进行分级时，应该直接进行测量，而不进行老化。

虽然有些LED光源在开始1000小时内亮度会有所增加，但由于一般只增加几个百分点，因此对测量结果影响不大。

在测量前，应该先在上述环境温度和空气流动的要求下运行一定时间以达到稳定状态，稳定时间一般为30分钟(小型集成式LED灯)到2小时以上(大型SSL照明设备)。

当产品在30分钟内的3次光输出和电功率的读数(15分钟读一次)变动不超过0.5%时，就认为产品已经达到了稳定状态。

此外，测量时SSL产品的朝向应根据制造商的建议或产品正常使用的状态来放置。

lm80测试报告是什么
近来⼩编遇到⼀些⼚商来咨询LM-80测试报告，说是客户要求⾃⼰的产品通过LM-80测试，这是个什么测试呢？产品做了LM-80测试报告有什么⽤呢？办理LM-80报告要提供多少样品？跟着美德检测⼩编去详细了解下LM-80测试吧！
Q：LM80测试报告是什么？有什么⽤？
A:LM-80报告是实验室声称依据IES LM-80测试⽅法进⾏测试，并根据标准要求出具的⼀份LED器件(LED
Package,Array,Module)的流明维持率测试报告。

LM-80报告可以证明产品的性能；也能⽤于终端产品的能效认证，⽐如灯泡在办理能源之星认证时，如果有LM80报告，可在灯泡⽼化3000H时先申请证书；没有LM80报告，要在灯泡⽼化6000H时才可以申请证书。

Q:哪些产品做LM-80认证检测？
A:LED器件：LED封装（贴⽚）、LED阵列（COB、灯丝）、LED模组
Q: LM-80的测试项⽬是什么？
A:流明维持率
（1）积分球测试（0H初始值、1000H、2000H…….5000H、6000H、7000H……9000H、10000H……）
（2）⽼化测试（6000H、9000H、10000H……）
Q:办理LM-80测试报告需要多少样品？
A:测试样品⼤于等于20个，Reported Life=6*测试时间；测试样品⼩于20个，Reported Life=5.5*测试时间。

封装：报告要求20pcs，建议客户每个温度25 pcs；
灯丝和COB: 报告要求10pcs，建议客户每个温度15 pcs。

Q:LM-80测试需要什么资料？
A:1.开案表：产品型号、电压、电流、测试温度、测试时间、系列型号。

2.灯珠规格书：产品尺⼨图。

LM79简介发布者: kema-bryant | 发布时间: 2010-12-7 08:45| 查看数: 585| 评论数: 10|帖子模式近期越来越多的美国买家要求LED灯具出具LM-79的测试报告，这一块也慢慢越来越受各个LED生产厂家的关注。

因为一般厂家的积分球满足不了该标准的测试要求，有一部分的项目需要借助分布式光度计才能完成，而一份完整的LM-79测试报告这些测试项目也都有要求，因此将此标准的简单介绍写下来，以供大家探讨。

IES LM-79-08标准内容简介：IES LM-79-08《固态照明产品电气和光度测量》规定了测量固态照明产品(SSL)的总光通量、电功率、光通强度分布和色度时，所应遵守的程序和注意事项。

标准适用于基于LED的、集成了控制电路和散热槽、因此只需要交流或直流电源便可运行的SSL产品;不适用于需要外部运行电路或外部散热槽(如LED芯片、LED封装、LED模块等)的SSL产品。

标准的第2到第8章介绍了产品在测量时的各种要求。

在测量时，环境温度和空气流动对于测量结果影响较大。

测量时的环境温度应保持在25℃±1℃，温度传感器应与SSL产品同高度，距离不超过1米，并避免受到SSL产品和其他光源的直接照射。

SSL产品的支撑装置应采用热传导性较差的材料(如聚四氟乙烯)。

测量装置内的空气流动应足够小，以免影响到装置所产生的正常的空气对流。

测量时还应当注意SSL产品的老化和稳定问题。

在对新的SSL产品进行分级时，应该直接进行测量，而不进行老化。

虽然有些LED光源在开始1000小时内亮度会有所增加，但由于一般只增加几个百分点，因此对测量结果影响不大。

在测量前，应该先在上述环境温度和空气流动的要求下运行一定时间以达到稳定状态，稳定时间一般为30分钟(小型集成式LED灯)到2小时以上(大型SSL照明设备)。

当产品在30分钟内的3次光输出和电功率的读数(15分钟读一次)变动不超过0.5%时，就认为产品已经达到了稳定状态。

LM-79 测试报告， LM-80 测试美国政府正式公布LED 检测标准号为：IES LM-79-08、IES LM-80-08、AMSIC78.377-2008。

美国能源部DOE 最新发布LED 灯具SSL 测试标准。

国际照明协会发布LED 灯的检测标准CIE 127，可按照 CIE 127 标准测试 LED 的发光亮度、角度、光通亮等，按照IEC/EN62471 检测LED 灯的光辐射安全，提供LED 灯的EN62471 检测认证。

光生物安全检测标准EN62471.美国LED 灯能源之星测试要求：按照IESNA-LM-79-08、IESNA-LM-80-08、IESNA-LM-63-02、主要测试LED 灯的空间光强分布。

配光曲线测试包括：IES 测试、空间光强分布、光强分布曲线、眩光等级、灯具效率、发光角度、总光通亮、电参数、LED 反射率。

一般能源之星测试认证周期，需要将近一年的时间，对于瞬息万变的国际市场，这个时间等于扼住了企业的咽喉，因此，众多的LED 厂商一直在摸索中寻求捷径，力求在节约成本的前提下尽快地获得走向国际市场的快速通行证。

LM-80 认证的推出，给大家带来了福音，可以大大的缩短认证周期，对于拥有LM-80 测试报告的公司，无疑等于拥有了一张快速通行证。

LM-80 测试对Case（壳体）温度Ts 和环境温度Ta 有严格要求，其要求Ta＞＝Ts-5°C，其中，壳体温度Ts 指距离LED 壳体1.5 毫米的空气中的温度。

目前国内实验室和封装厂家都是用精密恒温箱来实现LED 的恒温老化，但是，由于LED 本身发热量大，导致恒温箱只能精确控制环境温度Ta ，而不能精确控制壳体温度Ts，更控制不了壳体温度Ts 和环境温度Ta 的温度偏差在-5°C。

尤其是大功率的器件，发热量非常大，LED 的壳体温度Ts 会非常高，往往是壳体温度Ts 的实际温度远远高于所预设的温度，做了6000 小时后产品fail，最终的测试结果偏离，严重影响性能。