TW200805195A - Luminaries design platform and the method of processing the same - Google Patents

Abstract

The invention discloses a platform for luminaries design application and the method thereof. A community is provided to integrate with a luminary parameters, lighting design analysis module, and an interactive forum for registered members. The platform categorizes LED (Light Emitting Diode, LED) luminaries into groups of similar patterns and presents them pictorially, digitally, and cost-wise if necessary for easy assortment and reference. As for the comparison, the platform is attached with computer programs and instructions capable of conducting specific type of data calculation by themselves following platform users' evaluation-criteria selection. To assist illumination design engineers search the vast collection of data which may have been scattered around elsewhere, to evaluate the parameters of illumination sources and light fixtures, and to carry out in depth comparison and calculation among luminaries on the criteria chosen out of a previously constructed list. Via such an interaction, upper stream and down stream manufacturers of LED as well may query about such professional assistances and consultation as measurement of luminaries' photometric and spectral parameters and lighting design from the platform. Finally, a forum ground is incorporated into the platform to elicit discussions of unanswered questions pertaining to LED luminaries studies.

Description

200805195 IX. INSTRUCTIONS: [Technical field to which the invention pertains] The present invention relates to an application platform direct-integrated appliance integration application platform and method thereof. 〃 / '~别别, [Prior Art] Light Emitting DiGde, a solid-state light-emitting element made of materials, such as gallium phosphide (GaP), gallium arsenide (GaAs: germanium, Converting electrical energy into light, that is, $first principle, applying a current to the chemical element + conductor, through the combination of the pen and the pen hole, the excess energy will be released in the form of light, achieving the effect of light, which is cold Sexual luminescence, life expectancy of more than 100,000 hours. The biggest feature of the light-emitting diode is: no need for warming time (the reaction speed is fast (about 10-9 seconds), small size, electricity saving, financial shock, dyeing Low, suitable for mass production, high reliability, easy to meet the needs of the application to make very small or array of components. After the commercialization of the 7G era, the rapid development towards multi-color, high luminance and high luminous efficiency, successively Development of scale fossil t-gallium (GaAsP) high-luminance red neon diode and Shi Shenhua, recording (AlGaAs) green light-emitting diode, canned indium gallium (A1Gainp) high-luminance red light, orange light-emitting diode and Indium gallium nitride (GaInN) blue light Green light-emitting diodes. The use of light-emitting diodes has shifted from early warning and advertising to the general lighting field, especially after the practical use of high-brightness blue light-emitting diodes, resulting in white-light emitting diode lighting. The development trend of light sources has been highly valued by countries in Europe, America and Japan. With the use of high-brightness light-emitting diodes, the use of low-cost, high-efficiency rate can be achieved. The improvement of raw and clam shells will be the main direction for the future development of LEDs. The technical knowledge service program of the Ministry of Economic Affairs () also indicates the application of the High Brightness LED (ED). In addition to various display and traffic number lights, mobile phone screen colorization, mobile phone flash, lighting, LCD (lcd) backlight and automotive market are also emerging.

Ik with the development of lighting technology, the evaluation of future lighting sources is not only focused on the efficacy of the mouth, but also emphasize the lighting effect, light comfort, biological effects of light, light safety evaluation, and environmental performance, resources Consumed - flat mussels. When traditional lamps or similar products are compared with each other, in addition to the price difference, it is difficult for domestic general consumers or lighting design professionals to further compare the advantages and disadvantages of the products. Taiwan is a major producer of chip packaging, process development and manufacturing in the upper, middle and lower reaches of the world. It has innate advantages in R&D processes, and most of the general luminaire manufacturers belong to China _] 51 In terms of understanding relevant technologies and specifications, compared with advanced countries, such as German and Japanese multinational manufacturers, the information on lighting specifications is still uncommon. There are still many ambiguities in lighting design and LED applications. For example, when selecting lamps, the design profession does not rely on experience values. It is only possible to test the effects of lamps and samples, and it is difficult to face complicated lighting design. SUMMARY OF THE INVENTION Compared with traditional luminaires, illuminating diode (LED) luminaires are still new to the general public: S) 8 200805195. Although it has a large number of indicators superior to traditional lamps, the proportion of the surrounding environment is still low, and the relevant information is mostly foreign language, which is difficult to understand. At this stage, it is the crown of domestic LED production in the world. According to the embodiment of the present invention, an "integrated luminaire lighting application design platform" is provided to contribute to the improvement of the industry to enhance the light-emitting diode. The manufacture and popularization of new lighting fixtures.

&gt; In an embodiment, the present invention discloses a lighting fixture integration application. The system of the “Fengpingkou” system includes an input and output interface, which is used as an integrated application for lighting and lighting. 4 platform and external bridge; - database system, 1 to provide users with query, collection and modification of various luminaire data, basic specifications, light source data and luminaire time-dependent luminaire parameters; - interactive luminaire comprehensive attribute evaluation system, Coupling to the above database system, the above various luminaire parameter data are analyzed by multi-variables of parent interaction, and multivariate "multivariate scale attribute assessment" (MDPREF) is operated; - interactive forum, and database system:, as Discuss the related lighting application or measurement problems, and feedback the information in the database system; - Operational analysis module 'coupled to the database system 盥 interactive lamps 纟 m (four) estimate line, pure (four) materials, _ delivery of various Parameter information, processing and analysis of various parameters; - 3D image simulation module (three Dimensional, 3D), #合在库库系统盘式式灯式综合性评价系统" for the effect of analog lighting applications. In addition, an embodiment of the present invention further discloses a method for designing a platform, comprising the following steps: entering a lighting appliance integrated application design platform license to a lighting appliance integrated application design platform; Lusuke 'transfer member registration application lighting equipment integration application set 200805195 juice platform to review user qualifications, if permission, send permission notice to the user through the network interface, and establish member information in the member sub-database, if not, through the network The interface sends a message to inform the user to reject the application; the user = the database system query and the wide set of lighting materials, the data is analyzed and calculated by Wu, and 'analyze the types of lamps and the attributes of the lamps; (4) through the three-dimensional $ Like the analog module 'simulation lamps in various applications, the simulation of the effects of different types of lamps; user will be from the database (four) set of various • dynamic lighting integrated attribute evaluation system; users in the lamp /, risk Sub-system, select the attributes of more than one specific luminaire, and pass the selected attributes of the above 2 (4) Integrating the design platform to transmit the selected or standard message to the multi-scale attribute evaluation quantum system; making the attribute of =2, through the multi-scale attribute evaluation quantum system, analyzing and sorting according to the multi-scale method , output second-degree space attribute assessment coordinate map and lighting attribute ranking chart. In addition, according to the embodiment of the present invention, the lighting fixture is integrated with the == flat:: sorting and merging a large number of new light-emitting diodes and conventional materials::, even the reference price, convenient for quick retrieval or purchase. The J human body is a computer program that is externally attached to the design platform. Steps are carried out according to individual needs. #爷,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,, The interactive forum is used as a member to discuss issues with application or measurement. In order to accumulate the enthusiasm and expertise of the audience, indirectly establish and promote the illuminating two and application standardization projects. </ RTI> </ RTI> </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; In addition to the preferred embodiments herein, the present invention is also widely applicable to other examples. And the present invention is not limited to any embodiment, and should be construed as the scope of the appended claims and its equivalents. In the present specification, "a preferred embodiment" is intended to describe a particular feature, structure, or characteristic of a preferred embodiment. In the present invention, the number of embodiments is at least one. Therefore, the appearance of 2 in the present specification is not necessarily referred to the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in the preferred embodiments using any suitable method. $ ',,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,, Memory, display unit, input and output system 70, and network connection function, this is the unit that the computer system should have, but it should not be described in order to avoid the focus of the focus. This should be understood by those who know the skill. The invention discloses a lighting device integrated application design platform, comprising: an input/output interface 110 as a bridge for integrating the lighting device integration application design platform and the external; a database system 150 for providing a user to query, collect and modify various lamp materials, and basic Specifications, source data, and luminaire parameters for the application of the luminaire; an interactive luminaire integrated attribute evaluation system 200 coupled to the input and output interface and the database system 150,

11 200805195 /, is a multivariate analysis of the father's interaction with the parental interaction, operating the multivariate "multiple scale attribute assessment" (MDPREF), comparing the merits and demerits of the luminaire with the specific genus n of the user's priority consideration; An interactive forum, in conjunction with the database system 150, as a user to discuss related lighting application or measurement problems, and feedback information in the database system, in order to accumulate the wisdom and expertise of the people, indirectly establish and promote the light two Polar body ([rib) light source, lamp and application standardization project; an operational analysis module 13〇, the vehicle is combined with the data f system, the first 150 and the interactive luminaire comprehensive attribute evaluation system 12, receiving 2 library system 150 Passing various parameter information and processing the operation analysis of various parameters; a three-dimensional image simulation module 14〇(three Dimensi〇nai, ”) is coupled between the database system 150 and the interactive luminaire comprehensive attribute evaluation system 200 for Simulation of the effects of analog lighting applications. In the first embodiment of the present invention, in accordance with an embodiment of the present invention, wherein the database system, the first 150 includes a luminaire type image sub-data repository, for the user to query the relevant luminaire type; And the color light parameter sub-quantity φ material library 154 is coupled with the lamp type image sub-database 152, and receives the lamp type information transmitted from the lamp-type image sub-bunk library for the user to query - corresponding basic specifications of the k type And a light application reference sub-database 156, coupled to the basic specification of the lamp and the color light parameter = the library 154 and the lamp type image sub-stock library 152, received from the basic specifications of the lamp and The color light parameter sub-database 154 and the lamp type image sub-batch library 152, # correspond to the lamp type data and the basic specifications and the color light parameter data, and are used to simulate the application of the lamp through the three-dimensional image simulation module 14〇 Intended, with a member sub-library 158, storage integrated lighting appliances 12 200805195 integrated application design platform 100 members of the information. Referring to the second figure, in accordance with a preferred embodiment of the present invention, the interactive luminaire integrated attribute evaluation system 200 has a luminaire attribute subsystem 220 and a multi-scale attribute evaluation quantum system 210. The luminaire attribute subsystem 220 is coupled to the database system 150 and receives luminaire information from the database system 150. The multi-scale attribute evaluation quantum system 210 is coupled to the luminaire attribute subsystem 220, and receives the luminaire attributes from the luminaire attribute subsystem 120 through the operation analysis module 130, and analyzes the luminaire attributes according to the multidimensional Scaling (MDS) ❿ statistical analysis. . The luminaire property subsystem 220 includes light source parameters, luminance uniformity, illuminance, lifetime, price, manufacturer, lighting power per unit area, construction difficulty, three-dimensionality, saturation (UV), brightness, spectrum, light distribution Curves, color coordinates, Lab values (L*: Lightness brightness, a* · green/red axis red/green axis, b*: blue/yellow axis blue/yellow axis), light decay, luminous efficiency, red, green, blue ( RGB) Blending is the closest to white, energy, color rendering and other lighting attributes. When the user selects the specific fixture attribute evaluation option data in the fixture attribute subsystem 220, it is sent to the multi-scale attribute evaluation quantum system 210. The multi-scale attribute evaluation quantum system 210 performs multivariate analysis of the interaction parameters of the luminaire parameters through the analysis and calculation module 130 according to the multidimensional Scaling (MDS) statistical analysis, and operates the multivariate "multivariate scale attribute evaluation". (MDPREF), comparing the merits and demerits of the lamps with the user's priority considerations. Referring to the first and third figures, in accordance with a preferred embodiment of the present invention, a method for integrating an application design platform by a lighting appliance comprises:

13 200805195 (1) The user enters the lighting application integration application design platform ι〇0 through the network interface 180, and transmits the member registration application license to the lighting device integration application. also. Ten level σ 100 (step S 1 〇〇 ). As can be seen from the related operations and habits, this step can be connected to the relevant platform of the present invention by a browser through a personal computer or a terminal device. First, the user uses a personal computer or a similar device with a mobile terminal to access the lighting through the network interface 180 to integrate the application design platform 100, and send the member registration application information to the knowledge and Mingyi integrated application design platform. 1 00. (2) The lighting device integration application design platform 1) audits the user qualification, right permission, sends a permission notification to the user terminal through the network interface 180, and establishes the member information in the member information sub-database 158, and proceeds to step S104, if Otherwise, it returns to step sl1 (step si〇2). When the lighting fixture integration application design platform 100 receives the membership application sent by its user, and requests to obtain its membership, the lighting appliance integration application design platform ^ cores the qualifications of the applicant, if not permitted, through the network interface 180, If the license is granted, the lighting device integration application design platform 1 〇〇 in the member profile sub-database 158 'establish user-poor, and through the network Interface 1, send a member permission message to the user to obtain membership. (Step diagram) (3) The user enters the integrated lighting device integration application design platform 〇〇 ((4)S106)' self-database system 15〇 query and stratify the luminaire data, and the beaker material analyzes and calculates various lamps through the operation analysis module 13G. Types, lighting attributes. (Step S108) (4) Subsequently, the user has to pass through the three-dimensional image simulation module 14

14 200805195 The proposed luminaires are compared in different applications for different types of luminaires. (Step S110) (5) The processor of the present invention integrates the application design platform 100 by the user's request or signal indication to instruct the relevant database of the platform to send the above various lighting materials to the interactive luminaire comprehensive attribute evaluation system. 200. (Step S112) (6) Subsequently, the user has to input an instruction to the luminaire property subsystem 22 to select more than one of the attributes of the particular luminaire (eg, source parameter, luminance uniformity, illuminance, genius, price, manufacturer, Lighting per unit area, construction difficulty, three-dimensionality, saturation (UV), clarity, spectrum, light distribution curve, color coordinates, Lab value (L·*: Lightness brightness, a*: green/red axis Red/green axis, b*: blue/yellow axis blue/yellow axis), light decay, luminous efficiency, red, green and blue (RGB) mixed light closest to white, energy consumption, color rendering, etc.), the illumination of the present invention The appliance integration application design platform 100 transmits the selected object or target to a multi-scale attribute evaluation quantum system. (Step S114) (7) The genus of the luminaire selected by the user is analyzed and sorted by the multi-scale attribute metrics, and the first 210 is analyzed and sorted according to the multi-scale method, and the second-order spatial attribute evaluation coordinate map and the luminaire attribute ranking map are generated. (Step S116) Referring again to the second embodiment, in accordance with a preferred embodiment of the present invention, a method for integrating a lighting device with an application design platform also includes: (1) a user inputs an instruction through a computer or a terminal device, from the illuminator^ The integrated application design platform adopts parameters such as related lamp types, basic specifications, and color-light application methods or related knowledge (step S118) to evaluate

15 200805195 or subsequent processing. (2) The user enters the interactive forum 丨6〇 through the web interface to discuss the related lighting application or measurement problem (step sl2〇), but this is a selective step. (3) In addition, the user has to enter the database system 150 through the input and output interface 11 () to add the poor materials and feedback the lighting information, so as to accumulate the wisdom of the people and the professional poor communication and lighting equipment integration application design platform. data. (Step S122) • Referring to the fourth figure, the method for integrating the application design platform of the lighting fixture according to the preferred embodiment of the present invention also includes: (This portion is supplemented according to the above embodiment) (1) The user through the network The road interface is 8〇, enters the integrated lighting appliance integrated application design platform, and queries and collects the lamp data from the database system. (Step S200) (2) The user self-document system 15 灯具 luminaire type sub-data 152 _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ (Step S2〇2) (3) The luminaire type sub-database 152 will use the selected luminaire type beaker to correspond to the luminaire basic specification and the chromaticity characteristic sub-database 154. (Step S204) (4) The user queries the basic specifications of the collected lamp types and the color and light characteristics', and each type of lamp can correspond to the basic specifications of the lamp and the color and light characteristics. (Step S206) (5) The lamp application mode image sub-database 156 is received from the lamp type sub-barrel library 152 and the lamp basic specification and the color-light property sub-data library 154 16 200805195 corresponding day and shell material 'transmission operation analysis module The 13G and 3D image simulation module 140' provides a three-dimensional simulation of the luminaire application, and compares the effects of different luminaires in different applications. (Step S208), according to the embodiment of the present invention, 'refer to the fifth figure, for the lighting fixture integration = design platform _ the main menu 'user can board the design platform _ Neigu divided into five main esteems · / 1 \ ^ _ to ® mouth · (1) hair first diode lamp type image shell library 152 ' (2) lamp basic specifications and color characteristics database 154, (3)

Electro-optical-polar illuminator application 3D simulation image database, (4) Interactive illuminating diode luminaire property evaluation platform 2〇〇, (5) τυτ〇 help manual). ... First, the user selects the type of lamp, and refers to the classification window of the light-emitting one-pole lamp according to the sixth and seventh figures. There are many kinds of light-emitting diode lamps on the market. For the systematic marketing of this platform, it is necessary to propose an appropriate classification wood structure system. In recent years, white light high-efficiency light-emitting diode light source (light efficiency up to 35 40 lm/W or more) has been applied to general lighting for mass production, and Lu Lu has changed the atmosphere atmosphere of the full-color flow of LED light-emitting diode lamps. the difference. According to the difference of the application, for example, a combination of monochromatic white light and color light can be constructed. The classification items are as follows: 1. Color-emitting one-pole dynamic lamps: linear lamps series, visual lighting systems, IJ, Wall-mounted floodlighting series, other (matching system around the lamp, signal receiver and power supply, etc.). ^ 2·White light-emitting one-pole lamps: linear lighting series, visual lighting series, wall-washing lighting system, J, other (cooperating system, signal receiver and power supply, etc.).

17 200805195 For example, the series of lamps in the x four H贞 type is divided according to the function application. When the user selects the lamp, there is a drop-down reel for clicking. The expanded extension type space has been reserved here to increase the expansion flexibility of the subsequent database. The 2 names are named as the descriptive product. The company has issued the running water number ί,,, for example, the descriptive product name 1 (10), the serial number 101_0_15-00 12 ). When the user does not know how to distinguish the lamp, the name of the lamp : Directly get information. Icove is commonly known as wire troughing lamps; "2: Extremely Stereo Word Light Sources" is a graphic logo that can be applied to outdoor kanban fonts or recognized by industry. 第八 Refer to the eighth and ninth figures, which are light-emitting dipole color characteristics. 154. There are two types of data obtained from 2 ^ measurements, and the other is taken from the technical specifications of the filament. From the real two =:: = 2 two domestic and foreign lighting information has significant differences, because:, the difference between the two. However, consumers choose the LED light is likely to value several of the characteristics (attributes) to compare Yes::: The biggest factor in the effectiveness of the library is whether to collect mussels:: Parents, this time invested a lot of time to build a "sex:: degree country = out? Out of the name of the lighting kingdom, but only to the processing and production of shellfish, V to the small people to ignore the importance of such information. Classified into three screen data menus, ° and α ” window window luminaire basic specifications (external two and data are as follows: (1) luminaire number. (2) beam projection angle. (3) rated input voltage of the luminaire.

18 200805195 (4) Total wattage consumption. (5) Color photo of the front and back of the lamp. (6) Description of lamp attributes, dimensions, etc. 2. Light source data (internal specification data): (1) Light distribution curve. (2) Equal illumination distribution map. (3) Lamp color reference coordinates (color spectrum). (4) L* (light brightness value). (5) a * (color red/green value). (6) b * (color yellow/blue value). (7) Luminance (color luminance value). (8) X (color red light stimulus value). (9) Y (color light green light stimulus value; color light ciE 1931 lightness coordinate value). (1〇) Z (Color blue light stimulus value). (11) X (CIE1931 chromaticity coordinate value of color light). (12) y (CIE1931 chromaticity coordinate value of color light). (13) C* (light source chroma). (14) * (light source phase). (15) CCT (color versus color temperature, Kelvin). (16) CRI (luminance color coefficient). (17) Spectral Radiance (band spectrum of 380nm~780nm), main wavelength (color of light in human eyes), description of color distribution characteristics. The tenth and eleventh figures show the application of the light-emitting diode lamp

19 200805195 3D computer simulation, the number is expected to be quite large. Usually, when designers come up with simulation renderings, they can achieve realistic effects to some extent. It is a performance tool for the design industry to survive. However, many simulation softwares that can represent 3D do not allow the user to input the light distribution curve file (* ies ) of the luminaire. Therefore, it is impossible to pragmatically reflect whether the selected luminaire is in the right condition. This platform uses Lightscape, Lumen Designer, Dialux and other lighting computing software to calculate the illuminance of the immersive illuminance. In addition to obtaining approximate analog pictures, there is also illuminance calculation data. As shown in the seventh figure, the main window is divided into two sides, which can be used to compare the effects of lamps of different natures in the same scene. When the user operates, the light-emitting diode lamps to be replaced are selected according to the demand, and the scene will be ^ Corresponding effects, the left side is the scene drawn by the traditional light source, the edge is the use of the light two, the body lighting produces a more dramatic simulation scene, below the surface and provides a number of known red can click on the scene performance of different color light, so that the design profession through Imaged electricity, the polar body luminaire should be financially understood to understand the application results that may be achieved. The eleventh figure shows the comprehensive attribute evaluation system of the light-emitting diode lamp. 210° This is the most important function of the platform, and it is an innovative research result. = 斤 to put it in order to respond to the diverse characteristics of the illuminating diode lamp

Sit: In addition to: pay attention to the advantages and disadvantages of the single-characteristics of the lamps, you can also interact with the multivariate analysis method in Xiaoshan* to solve the design work. This part = reach this complicated case (plain text slot, *txt) ^ The external 4 increased 灯具 luminaire measurement original broadcast platform 1 〇〇 _ _ 10 = even = small calculation program. Some of these programs and programs are for the download of the brain programming language, and other parts of the free statistical sharing software. The user does not need to use the 200805195 Jingdi operation program. Just click the button and the evaluation option to enter the program. 仏~2 Perform the algorithm or the edge map, and then judge the ranking according to the result. After the project's ranking is decided, the so-called Multi-Eryton Scale Attributes Assessment (MDPREF) can be further manipulated. As shown in the twelfth figure, the layout configuration, the menu block at the upper and lower ends of the window are the evaluation attribute name, the name of the light diode lamp, etc., and there are 6 sets of evaluation items. The number can be increased and revised according to the 21 groups listed in the four figures. The central blank portion of the window is reserved for the program to perform individual project evaluations. Φ帛十—The graph is not the execution of the multi-color spectral reflectance curve comparison program. The horizontal drawing of the coordinate map represents the bird m~78〇= see light” 直$ straight axis is “wave radiation intensity. There are many reflection curves in the eye. The Ge table has different k-shapes, and its special imitation reflects the three properties of the color light. Such as in the picture

Blastl2, (10)6 deletes the main wavelength of 6 (the light energy in the coordinates is taken from:), corresponding to the position of 46〇nm blue light, (4) the color of the light source will be biased towards the color: in other words, 'this two lamps are suitable for illuminating blue The object makes it more prominent in blue saturation. In addition, the slope and area of the curve reflect the % and brightness of the color, respectively. The total energy obtained by integrating the area source light in the arc represents the total amount of light beams radiated by the luminaire. The larger the area, the higher the brightness. For this reason, it is better to compare the two curves to see the difference in color between the lamps. This kind of picture can also understand the color rendering of the light source and compare the cross. At this time, it is important to pay attention to whether the number and height of the peaks of the curve are similar. In general, the visible light wavelength of the high color rendering light source is large and average, so that the basic definition can be satisfied. Basically, the proof of color rendering needs to represent the breadth of visible light with 8 color samples, and test the average color difference after illumination of the light source (see 21 200805195). Although the visual reflection curve cannot find the color rendering coefficient, the color rendering of the luminaire. In fact, as mentioned above, the color of color light... There is a sense of righteousness, but basic derogatory is just absolute. ’, that is, when the two lamps are compared with the color rendering coefficient, the numerical value and the chromaticity must be high. The lower value of the 'reflection curve may be extremely: biased long wave or short wave' but the same reflection wavelength:

"Color rendering. This kind of visual rating ranking is in need of the object to be illuminated = 疋 not this single shoulder coefficient. The design platform in this project discriminant: 頟 add the function of the enlarged graph to distinguish the graph over approximation The difference is not significant. Conversely, when the difference is too large, there is also a curve drawn by the logarithmic data (natural logarithm 〇0g). ^See the thirteenth figure, when the five-inch LED The four-inch full-color luminaires in the luminaire are all white-lighted, and the color rendering is compared with the monochromatic white light of 1WMR. Only the basic definition position of color rendering can be adopted. The figure shows that only the wavelengths of:,,,,,,, Its color rendering is better than other lamps, and its visible Ic0ve curve is also close to the distribution of red, green and blue wavelengths, and the degree is gentle, with sub-optimal color rendering. Other three-color mixed-color lamps are red, green, The blue wavelength intensity difference is large 'and the short wave volume is large'. For the cool color object, the color rendering is better. The absolute color rendering coefficient is not too high. On the other hand, the full color, light diode lamp is applied to the situation shaping change. Sexuality, It is not as important as monochromatic light source, unless the color of the situation color has special requirements, relying on the luminaire to catalyze its saturation, otherwise, the color rendering is not meaningful under the dynamic color change.

22 200805195

CRI Σα (color rendering coefficient calculation formula)

Ri = 100-4.6 Ei ^ = )2

Figure 14 shows a comprehensive comparison of lamp energy consumption and electricity costs. If the design professional wants to know whether the LEDs are really rumored, it is highly energy-efficient. Just click on the energy-consuming data in the various lamp databases in this platform to solve the confusion. A rough review of the data in the figure below, comparing the three lamps with the same wattage specification, we can see that the energy consumption of the two-color full-color 5〇w LED lamp is 69.654W and 7106W respectively; 5 made by Philips (phiHps) 〇W MR16 traditional lamp white light cup lamp energy consumption is a retelling. As far as the data is concerned, it seems that this verification overturns the rumor that the LED lamp is more power hungry. Of course, this is caused by the need to activate the light source with the power controller. Deducting it, virtually all LEDs are significantly lower than the wattage listed in the factory specifications, below 5〇w. The rumor is true. Coupled with its durability and weather resistance, LED lamps are clearly superior to traditional lamps in terms of energy efficiency. The same towel can allow the platform maker to quickly grasp the energy consumption message. It can also calculate the electricity cost calculation result, or manually calculate the monthly electricity cost per month. Figure. The uniformity is defined as a single - the fifteenth figure shows the uniformity of the illuminance of the luminaire (Uniknnity) compared to the highest value of the luminaire projected in the fixed range minus 200805195. The average value divided by the lowest value minus the average value and multiplied by 100% The percentage value obtained. That is, the uniformity is a review of the distribution of luminosity within the projection range of the luminaire. The greater the average back, the more uniform the luminosity distribution. As far as the needs of lighting design are concerned, in order to have a uniform wall washing effect (Wall_wash), it is necessary to provide a luminaire with a uniform illumination. Conversely, when it is necessary to focus on and focus on the illumination, it is necessary to have a smaller backlight. The figure below shows the illuminance values of the five luminaires projected in the same range and at the same grid point, and the overall comparison map presented in the scatter plot. However, in this stage of the experiment, only the left half of the light-emitting range is captured, and the right half of the light-emitting data is not input. Each of these curves is a regression line generated by the operation of the mother luminaire scatter plot to represent the uniformity of the illuminance distribution. Usually, since the light distribution intensity of the lamp gradually decreases from the axial outer side of the lamp, it is inevitable that the numerical value of the coordinate map gradually decreases from left to right. It is only the trend of numerical change that shows dramatic variation or not, which can be used as the basis for the average degree of back. That is, the larger the slope and the curvature of the curve, the smaller the uniform f is, and the more uniform the smoothness is. For the conglomerate with a narrow beam angle, it is foreseeable that the regression curve must have a large slope and curvature. Figure 16 shows the light distribution curve comparison array. The light distribution of the luminaire uses the k /, the inner reflector or the grid book to control the light direction and intensity of the beam. In this case, the same light source is assembled in the lamps of different light control mechanisms, which can produce different knives. The representation of the light distribution results, the internationally more common tool is the International Engineering Society 〇f N〇rth

Polar coordinate vector curve® set by AmenCa, IESNA). JL has different kinds of representations, so I will go there temporarily. With this tool, you can choose the right light distribution according to the degree and function when designing the professional lighting fixture.

24 200805195, table. The ten-turn graph is the information attached to the luminaire, which is too scattered. This design: The station provides the function of centrally comparing arrays' for visual comparison. When the user selects the key lighting required to display the product, the A-CCENT | mercerized light in the figure can be selected. In contrast, it is necessary to be able to provide a large range of uniform illumination, and the broad form of the technique (commonly known as the batwing-shaped light distribution) will be more suitable. In addition, since it is a coordinate map, there must be data representing the intensity of luminosity. It is only for the lamps with different intensity distribution to be drawn in the frame of a certain scale, the value of the value is difficult to compare, and it is necessary to compare the figures as shown above, and to display them in the same way in a juxtaposition, which is more efficient. Determine the order of the light distribution. Figure 17 shows a comparison of CIE1931 color coordinates. Each fixture has a chromaticity coordinate X, y value, and a small black dot indicates the color of the color in the color map. The design platform further provides a multi-turn luminaire with the same coordinates for comparison, allowing the design professional to arrange the preferred ranking of chromatic light. Of course, the location of the small black dots also reflects the relative color temperature of the color light, which is also helpful for the selection of the color rendering of the luminaire. For example, when it is necessary to select a warmer light source, it is possible to pick up white light below 3000K, and when a relatively cool color temperature is required, select a light source near 6000K in white light. Examine the arrangement of the small black dots in the figure below. It can be seen that the color temperature sequence of white light mixing of the light-emitting diode lamps at this stage reflects the color temperature from right to left from low to south, and the color is from yellow to purple, respectively IWMR, iw Blastl2 , ICove, ColorBrustl2, ColorBurst6. Among them, the color temperature of IWMR is the most yellowish, and the color temperature of c〇lorBurst6 is biased. Figure 18 shows the CIELab three-dimensional spatial chromaticity coordinate map. Compared with 25 200805195, the CIE1931 color coordinate map only provides the second spatial position of the color light, and the CIELab map has more brightness coordinates, which can accurately grasp the color of the color light. This platform combines this small program to show the relative position of the color light of multiple lamps at the same time. The circular color map of Figure I is equivalent to the CIE1931 chromaticity coordinate map, showing red, inspection, re-, green to purple full-color phase. Similarly, the area near the center point indicates that the color saturation is low, and the vicinity of the circumference indicates that the saturation is high. What is added to cIELab is that this circular color map can rise and fall according to the brightness (1) value. When rising to the apex, the L value approaches 1〇〇, and the color map will appear all white, and vice versa. In the figure, the position of the illuminating light is also indicated by a small black dot, but it is easier to visually grasp the result of the change of the color illuminance, which is more reliable than the CIE1931 chromaticity diagram. In other words, the above-mentioned five-light luminosity bird's-eye view of the bird's-eye view is in the order of the curve-arranged color position's off, which can be rotated at 36G degrees to see the arrangement of the five luminaire colors in the three-dimensional space. According to the embodiment of the present invention, after the relationship between the independent attributes is further improved by the comparison process of the single item, the design professional can fill in the ranking data in the attribute evaluation blank form (refer to the nineteenth figure). To perform statistical analysis of the next-stage multivariate decision making. The attributes of this stage are determined by the check of the previous stage, and the quantity can be more or less. See the number of miles 疋 The twenty-fifth figure is the multi-scale method (Mul touches the mensional Scaling, referred to as MDS) towel MDPREF, the calculation results of the statistical program. When investigating the number of illuminating diode lamps (stimuli), it can be compared according to the user's decision-making, which is most concerned with the three items or the most comprehensive evaluation index of the three attributes. After the calculation, the relevant position of the luminaire and the evaluation project is fixed at 200805195. According to the diagonal of the center point of the coordinate, the principle of the edge of the circle is two: the product of the iterative process is shown in the figure. That is to say, there are several evaluation projects that are the same as the generation line. As shown in the figure, the luminaire and the line are positive = the distance in the f is representative. The shorter the distance, the more the projection value is the evaluation item. Conversely, the larger the negative value, the worse the evaluation result. ' is a table as shown in the twentieth-figure. The table vertical ‘:乂:? shadow value, the red part is (3) sorted i get:;: one:: is the best choice. The present invention is described above with reference to the preferred embodiments, but it is not intended to be used. Others: Li Ganwei and its equivalent fields. Any technical familiarity with this field belongs to::: the equivalent change or design done under the spirit of the invention disclosed in the spirit or scope of this patent, and should be G 3 in the following patent application scope Inside. BRIEF DESCRIPTION OF THE DRAWINGS For the purpose of illustrating the first diagram, a system diagram, in accordance with an embodiment of the present invention, the illumination n has an integrated application design platform architecture. The second figure is an architectural diagram, according to an embodiment of the present invention, a relationship between a f-system of a luminaire and a multi-scale attribute sub-system. FIG. 1 is a flow chart of a luminaire integrated application design platform according to an embodiment of the present invention. method.

27 200805195 The fourth figure is a flow chart for explaining the coupling correspondence of each sub-database in the database system according to an embodiment of the present invention. The fifth figure is an embodiment for describing a main menu of a lighting appliance integrated application design platform. The sixth figure is an embodiment for describing a light-emitting diode lamp type database window of a lighting appliance integrated application design platform. The seventh figure is an embodiment for describing a light-emitting diode lamp type database window of a lighting appliance integrated application design platform. The eighth figure is an embodiment for describing a basic specification and a color light parameter database of a light-emitting diode lamp for a lighting appliance integrated application design platform. The ninth embodiment is an embodiment for describing a basic specification and a color light parameter database of a light-emitting diode lamp for a lighting appliance integrated application design platform. The tenth embodiment is an embodiment for describing a three-dimensional computer simulation of a lighting diode application for a lighting fixture integrated application design platform. The eleventh embodiment is an embodiment for describing a three-dimensional computer simulation of a lighting diode application for a lighting fixture integrated application design platform. The twelfth embodiment is an embodiment for describing a comprehensive attribute evaluation of a light-emitting diode luminaire for a lighting appliance integrated application design platform. The thirteenth embodiment is an embodiment for describing a lighting fixture integrated application design platform, and a spectrum of integrated attribute evaluation of the light-emitting diode luminaire. The fourteenth embodiment is an embodiment for describing a lighting appliance integrated application design platform, and an energy consumption meter for comprehensive attribute evaluation of the light-emitting diode lamp. The fifteenth embodiment is an embodiment for describing a lighting appliance integrated application design platform, and the uniformity of the comprehensive attribute evaluation of the light-emitting diode lamps.

28 200805195 The sixteenth embodiment is an embodiment for describing a lighting fixture integrated application design platform, and a light distribution curve of the integrated attribute evaluation of the light-emitting diode lamp. The seventeenth embodiment is an embodiment for describing a lighting fixture integrated application design platform, and a color coordinate of the integrated attribute evaluation of the light-emitting diode lamp. An eighteenth embodiment is an embodiment for describing a lighting fixture integrated application design platform' Lab for comprehensive evaluation of its illuminating diode luminaire. The tenth figure is an embodiment for describing a lighting appliance integrated application design platform, and an attribute evaluation form for the comprehensive attribute evaluation of the light-emitting diode lamp. • 帛 [10-tutorial-implementation, which is used to describe the lighting application integration application design platform, and the second-order spatial property evaluation coordinate map of the integrated attribute evaluation of the LED illuminator. The twenty-first embodiment is an embodiment for describing the lighting attribute integration of the lighting fixture integration application. The luminaire attribute row of the comprehensive attribute evaluation of the luminaire-integrated luminaire is φ [Main component symbol description] 100 illuminating device integration application design platform 110 output interface 120 Interactive luminaire comprehensive attribute evaluation system 130 Operation analysis module 140 Three-dimensional image analysis module 150 Database system 152 Lamp type image Sub-database 154 Lamp basic specifications and chromatic parameters Sub-database

29 200805195 156 Luminaire Application Sub-database 158 Member Sub-database 160 Interactive Forum 180 Network Interface 200 Interactive Luminaire Integrated Evaluation System 210 Multi-Scale Attribute Evaluation System 220 Luminaire Attribute Subsystem Steps S100, S102, S104, S106, S108, S110, S112, S116, S118, S120 〇Steps S200, S202, S204, S206, S208. , §)

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Claims (1)

200805195 X. Patent application scope: 1. A system integrating integrated lighting design application platform, including: Wheel access interface as a communication bridge for integrating lighting equipment integration application design platform with external environment; Shell library system 'for providing use Query, collect and modify various luminaire parameters of poor materials, basic specifications, light source data and lighting application methods; Luyi interactive luminaire comprehensive attribute evaluation system, coupled to the above database system to interact with the above various luminaire parameters Multivariate Analysis of Roles' #Multivariate Attribute Assessment (MdpreF); an interactive forum, coupled with the database system, as a user to discuss related lighting application or measurement issues, and feedback information The database system; the one-transportation analysis module is coupled between the database system and the interactive luminaire comprehensive attribute evaluation system, and receives various parameter information transmitted by the database system to process various parameters; _-dimensional image simulation module Group (three Dimensional, 3D), fits into the database system and Comprehensive Evaluation System property between the movable lamps, the effect of lighting applications for analog simulation. 2. The system of the integrated lighting fixture integrated application design platform of claim 1 of the patent application, wherein the database system includes: a lamp type image sub-database for the user to inquire about the type of the lamp; k basic data and color light parameter sub-database, and the type of the lamp 31 200805195 coupled with a sub-database, receiving the type information of the lamps transmitted from the image sub-library of the lamp type, for the user to inquire about the basic specifications and color-light parameters of the corresponding lamp type; a lamp application mode sub-database, coupled to the The basic specifications of the lamp and the sub-data library of the color and light parameters and the image sub-library of the lamp type are received from the basic specifications of the lamp and the color light parameter sub-database and the image sub-library of the lamp type, and the corresponding lamp type data and basic specifications And color light parameter data, used to simulate the effect simulation of the lighting application; and a member sub-library to store information on the integrated lighting device integration application design platform members. ° 3. As in the scope of the patent application, the integrated lighting fixture integration application design flat = system 'the luminaires described in the time library f library received from the k basic specifications and color light parameters sub-database and the luminaire The type image sub-library, which corresponds to the type information of the lamp and the basic specifications and color-light data, through the simulation of the effect of the three-dimensional image simulation module 'simulation lamp application. 4. : Apply for the patent scope! The integrated lighting fixture integrated application design flat mouth system, wherein the interactive luminaire comprehensive attribute evaluation system includes: a luminaire attribute subsystem and a f-warehouse system _, receiving luminaire information from the database system; The scale attribute evaluation quantum system is coupled to the luminaire attribute subsystem 32 200805195, receives the luminaire attributes from the luminaire attribute subsystem, and analyzes the luminaire attributes according to the multidimensional Scaling (MDS). 5. The system of the integrated lighting fixture integrated application design platform of claim 4, wherein the luminaire property subsystem comprises one of the following parameters or any combination thereof: light source parameter, luminance uniformity, Illuminance, illuminance uniformity, life, price, manufacturer, lighting power per unit area, construction difficulty, three-dimensionality, saturation (UV), brightness, etc., spectrum, light distribution curve, color coordinates, Lab value (L * : Lightness brightness, a* ·· green/red axis red/green axis, b* ·· blue/yellow axis blue/yellow axis), light decay, luminous efficiency, RGB mixed light closest to white, energy consumption, color rendering Sex and so on. 6. The system for integrating the lighting device integration application design platform of claim 4, wherein the multi-scale attribute evaluation quantum system performs the multivariate analysis of the interaction of the lamp parameters through the operation analysis module. The multivariate “Multivariate Attributes Assessment” (MDPREF) compares the pros and cons of the luminaire with the user-preferred considerations. 7. A method for integrating a lighting device to integrate an application design platform, comprising: the user querying and collecting the lamp data from the database system, and the data is analyzed by the analysis operation module to analyze the types of the lamps and the attributes of the lamps; Like analog modules, analog luminaires are used in various application fields 33 200805195 to simulate the effects of different types of luminaires; users send various luminaire data collected from the database system to the interactive luminaire comprehensive attribute evaluation system. 8. The method for integrating the lighting device integration application design platform according to claim 7 of the patent scope, wherein the user enters the lighting device integration application design platform through the network interface, and transmits the member registration application permission to the lighting device integration application design platform. 9. The method of integrating a lighting fixture integrated application design platform according to claim 7 of the patent scope, wherein the lighting fixture integrated application design platform reviews user qualification, and if permitted, sends a license notification to the user through the network interface, And establish member information in the member sub-database, if not, send a message through the network interface, notify the user to reject the application. 1010. The integrated lighting appliance integration application design platform=method of claim 7 of the patent application scope, wherein the user is inquired from the lamp type sub-database and the gas collection type information. U. The method for integrating a lighting fixture integrated application design platform according to claim 7 of the patent scope, wherein the luminaire type sub-database will use the selected luminaire type data to correspond to the luminaire basic specification and the chromaticity characteristic sub-database . 34 200805195=Applicable to the patented model (4), the method of integrating the lighting fixtures into the design of the flat panel, wherein the user inquires about the basic specifications and the chromatic properties of the type of boarding, and each type of luminaire can correspond to it. Lights and basic specifications and chromatic properties. 〃 ^Application for the scope of patent application No. 7 Integrated lighting appliance integration application design Ping: The method of the luminaire application method image sub-library received 2 lamps (four) sub-database and lamp basic specifications and chromatic properties ^tj·(4) 'Through the 3D image simulation module' to provide a 2D stereoscopic simulation of the luminaire application, compare the lamps of different natures, and compare the effects in different applications. The situation spreads to the multi-scale genus|Study of the quantum system = the application of the patent scope of the seventh item of integrated lighting equipment integration application design Ping 2 method 'the ones mentioned in the luminaire attribute sub-system, select more than The attributes of the specific luminaire, and the selected attributes, 透鲁Μ, 、,月, are selected objects or Bq tii 6 ^ w _ ^ • ♦ Patent scope item 7 Integrated lighting device integration application design Ping: The method of the user-selected attributes described above, through the multi-scale wide-scale attribute evaluation quantum system, through the operation analysis module, according to multi-scale knife sorting, output second-degree space attribute evaluation Quantity coordinate map lighting attribute ranking chart. 35 200805195 16· The method for integrating the lighting device integration application design platform according to the scope of patent application No. 7 also includes: The user enters an interactive forum through the network interface to discuss related lighting application or measurement problems; Through the import and export interface, access to the database system to enhance the information, feedback on the lighting information, in order to accumulate the wisdom and professional information of the people and the two integrated applications of the §10 platform. 36