Lighting Design Principles Lecture 1.ppt
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The document outlines essential lighting design principles, including key terms and their units such as luminous flux, illuminance, and luminous efficacy. It explains the light spectrum, the parameters influencing light perception, and the impact of various light sources on color rendering and quality. Additionally, the document covers calculations for artificial lighting to achieve desired illumination levels and highlights the importance of color temperature and light yield in lighting design.
![Parameters
Parameter Symbol Unit
Luminous flux Φ lumen [lm]
Luminous efficacy η lumens per watt [lm/W]
Luminous energy Q lumen seconds [lms]
Light yield I candela [cd]
Illuminance E lux [lx]
Daylight factor D percentage [%]
Light density L candela per m² [cd/m²]
Colour temperature - Kelvin [K]
Colour rendering index Ra -
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2024/2025 Eng. Anan Kakani](https://image.slidesharecdn.com/lightingdesignprincipleslecture1-241008075721-4146e424/85/Lighting-Design-Principles-Lecture-1-ppt-2-320.jpg)
![Luminous flux, luminous efficacy and the
quantity of light
• Luminous flux Φ [lm] shows how much light is radiated from a light
source. To establish this fact, the human eye is needed as an
evaluating organ. When calculating the luminous efficacy, the
quantity of light, the light yield and the luminance, it is essential to
regard luminous flux as a baseline value.
6
2024/2025 Eng. Anan Kakani](https://image.slidesharecdn.com/lightingdesignprincipleslecture1-241008075721-4146e424/85/Lighting-Design-Principles-Lecture-1-ppt-6-320.jpg)
![Light yield I [cd]
• Light yield I [cd] determines the
ratio of light emitted by a light
source moving in a specific
direction.
• The luminous intensity of natural
light sources can be influenced by
the use not only of sun-shade and
glare protection, but also of glazing
and light control.
• In the case of artificial light, these
are the essential light models and
light sources/illuminants used.
7
2024/2025 Eng. Anan Kakani](https://image.slidesharecdn.com/lightingdesignprincipleslecture1-241008075721-4146e424/85/Lighting-Design-Principles-Lecture-1-ppt-7-320.jpg)
![Illumination densities
• In the case of illuminance E [lx; lm/m²], the luminous flux represents
a specific illuminated area.
• When illuminating workplaces, extensive normative specifications
determine which values are reached or should not be exceeded.
• In the case of daylight planning, the decisive values are generally the
readily available illumination intensities of natural light sources;
• When planning artificial lighting, calculations should be made, and
simulation models calculated to ascertain which lights and illuminants
will be needed to produce the necessary illumination intensity
9
2024/2025 Eng. Anan Kakani](https://image.slidesharecdn.com/lightingdesignprincipleslecture1-241008075721-4146e424/85/Lighting-Design-Principles-Lecture-1-ppt-9-320.jpg)
![The illumination intensities of natural light
sources on the ground
Light source Luminance [lx]
Clear sky, sunny (summer) 90,000–130,000
Clear sky, sunny (winter) 19,000–25,000
Cloudy sky (summer) 15,000–20,000
Cloudy sky (winter) 5,000–8,000
Dusk 3–750
Moonlight 0.02–0.30
10
2024/2025 Eng. Anan Kakani](https://image.slidesharecdn.com/lightingdesignprincipleslecture1-241008075721-4146e424/85/Lighting-Design-Principles-Lecture-1-ppt-10-320.jpg)
![Exemplary colour temperatures of natural
and artificial sources of light
The source of light Colour temperature [K]
Candle 1,500
Light bulb (60 W) 2,700
Light bulb (200 W) 3,000
Halogen lamp (12 V) 3,000–3,200
Fluorescent lamp (neutral white) 4,000
Morning/evening sun 5,000
Cloudy sky 6,500–7,500
Fog/haze 7,500–8,500
Clear sky 9,000–12,000
16
2024/2025 Eng. Anan Kakani](https://image.slidesharecdn.com/lightingdesignprincipleslecture1-241008075721-4146e424/85/Lighting-Design-Principles-Lecture-1-ppt-16-320.jpg)
Lighting Design Principles Lecture 1.ppt
- 1. Lighting Design Principles 1. Physics terminology and parameters 2024/2025 Eng. Anan Kakani 1
- 2. Parameters Parameter Symbol Unit Luminous flux Φ lumen [lm] Luminous efficacy η lumens per watt [lm/W] Luminous energy Q lumen seconds [lms] Light yield I candela [cd] Illuminance E lux [lx] Daylight factor D percentage [%] Light density L candela per m² [cd/m²] Colour temperature - Kelvin [K] Colour rendering index Ra - 2 2024/2025 Eng. Anan Kakani
- 3. Terms, Units, and Definitions Photometrische Größe SI unit and calculation Definition Luminous flux Lumen (lm) The measure for the total amount of light emitted by a light source. Light intensity Candela (cd) = lm/sr The ratio of lumen to radiation angle. Gives information about how much light is radiated in a certain direction. Illuminance Lux (lx) = lm/m² The measure for the light that arrives at a receiver surface. Luminance cd/m² The measure for the impression of brightness of a surface, perceived by the human eye. Luminous efficacy lm/W The ratio of emitted luminous flux to required electrical power. Light quantity lm*s The total luminous flux emitted by a light source over a certain period of time. 3 2024/2025 Eng. Anan Kakani
- 4. The light and colour spectrum • To the human eye, only a minuscule part of the electromagnetic spectrum is perceptible. This field is known as the light or colour spectrum. It is also frequently referred to as natural “light”. • Higher-frequency ranges with short wavelengths (such as UV or X- rays) and low-frequency ranges with long wavelengths (microwaves and radio waves) are invisible to the human eye. Within the range of the visible light spectrum, it is possible to determine the diverse wavelengths of the colour tones 4 2024/2025 Eng. Anan Kakani
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- 6. Luminous flux, luminous efficacy and the quantity of light • Luminous flux Φ [lm] shows how much light is radiated from a light source. To establish this fact, the human eye is needed as an evaluating organ. When calculating the luminous efficacy, the quantity of light, the light yield and the luminance, it is essential to regard luminous flux as a baseline value. 6 2024/2025 Eng. Anan Kakani
- 7. Light yield I [cd] • Light yield I [cd] determines the ratio of light emitted by a light source moving in a specific direction. • The luminous intensity of natural light sources can be influenced by the use not only of sun-shade and glare protection, but also of glazing and light control. • In the case of artificial light, these are the essential light models and light sources/illuminants used. 7 2024/2025 Eng. Anan Kakani
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- 9. Illumination densities • In the case of illuminance E [lx; lm/m²], the luminous flux represents a specific illuminated area. • When illuminating workplaces, extensive normative specifications determine which values are reached or should not be exceeded. • In the case of daylight planning, the decisive values are generally the readily available illumination intensities of natural light sources; • When planning artificial lighting, calculations should be made, and simulation models calculated to ascertain which lights and illuminants will be needed to produce the necessary illumination intensity 9 2024/2025 Eng. Anan Kakani
- 10. The illumination intensities of natural light sources on the ground Light source Luminance [lx] Clear sky, sunny (summer) 90,000–130,000 Clear sky, sunny (winter) 19,000–25,000 Cloudy sky (summer) 15,000–20,000 Cloudy sky (winter) 5,000–8,000 Dusk 3–750 Moonlight 0.02–0.30 10 2024/2025 Eng. Anan Kakani
- 11. Light density • Light density is the parameter within physics that describes the brightness experienced by human beings. It is one of the few units extremely dependent on the direction of a light source. • luminance is always dependent on a generator and not — as in the case of most other parameters — on the recipient of the light radiation, i.e., the human eye. • The awareness of darkness and glare through the perception of diverse sensitivities of the eye varies according to the eye’s sensitivity. Not only that, but the eye also adapts itself to certain situations over time. • The wavelengths of light, that is, the perceived colour, ensure that similar light densities trigger differentiated feelings 11 2024/2025 Eng. Anan Kakani
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- 13. The perception and sensitivity of the human eye Viewing task Light density Night vision 3–30 µcd/m² – 3–30 mcd/m² Twilight 3–30 mcd/m² – 3–30 cd/m² Daylight > 3–30 cd/m² Dazzle > 100,000–1,000,000 cd/m² 13 2024/2025 Eng. Anan Kakani
- 14. Light/bright colour and colour temperature • Luminous colour or colour temperature (unit of measure: Kelvin) describes a colour impression produced by a light source. • A lower value alludes to a large share of red in the existing colour spectrum, in which subjective perception is experienced as warm. Above all, in the planning of the temperature, the colour plays a significant role in determining the artificial light sources since the planning goal generally is to simulate natural light. • The technical capabilities generally end with colour temperatures well below those of natural light. Light sources with a colour temperature of under 3,300 K are registered as warm-white and have a neutral white spectrum fluctuating between 3,300 and 5,000 K; higher values result in warm “daylight white” or ”cold white” light sources. 14 2024/2025 Eng. Anan Kakani
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- 16. Exemplary colour temperatures of natural and artificial sources of light The source of light Colour temperature [K] Candle 1,500 Light bulb (60 W) 2,700 Light bulb (200 W) 3,000 Halogen lamp (12 V) 3,000–3,200 Fluorescent lamp (neutral white) 4,000 Morning/evening sun 5,000 Cloudy sky 6,500–7,500 Fog/haze 7,500–8,500 Clear sky 9,000–12,000 16 2024/2025 Eng. Anan Kakani
- 17. The colour rendering index • The colour rendering index Ra displays the quality of the colour rendering of diverse light sources. The process describes the impact evoked by light directed at objects and other people. • Good colour renditioning is achieved when a natural colour environment is optimally reproduced (value Ra=100). In high-quality interiors with good residential quality and/or workplaces with light sources, an Ra < 80 should not be used. The colour rendering index Ra refers to the eight most frequently used test colours. The index makes this quite clear and means “in general” in this context. 17 2024/2025 Eng. Anan Kakani
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- 19. Colour reproduction index with diverse light sources Source of light Colour rendering index Ra Light bulb Up to 100 LED 80–97 OLED 80–90 Fluorescent lamp 50–98 Metal halide lamp 60–95 High-pressure sodium lamp 18–85 High-pressure quicksilver lamp 45 Low-pressure sodium vapour lamp < 44 19 2024/2025 Eng. Anan Kakani