Revision as of 11:03, 19 January 2015

Overview

A short overview of the terminology:

Luminous Intensity

Luminous intensity is a measure of the amount of light originated from the source, its light output, the unit of which is the candela (cd).

Luminance

Luminanceis a measure of the brightness of a particular surface if considered as a large light source. A common unit of luminance is cd/m².

Luminous Flux

Luminous flux (or luminous power) is the quantity of light energy emitted in all directions. The unit of luminous flux is lumen (lm). One lumen is the luminous flux of the uniform point light source that has luminous intensity of 1 candela (cd) and is contained in one unit of spatial angle (or 1 steradian).

Steradian is the spatial angle that limits the surface area of the sphere equal to the square of the radius. If the radius of the sphere is 1 metre, which implies its area to be 4πr², then the luminous flux of the point light source of 1 candela is 4π lumens, as shown in Figures 2 & 3.

Figure 2 & Figure 3

For instance, a light source can be emitting light with an intensity of one candela in all directions, or one candela in just a narrow beam (as in most LEDs). The intensity is the same but the total energy flux from the lamp, in lumens, is not the same. The output from a lamp is usually quoted in lumens, summed over all directions, together with the distribution diagram in candela.

Illuminance

Illumincance is a measure of the amount of light falling on a particular surface. Its unit is lux (lx), defined as equal to one lumen per metre squared (1 lm/m²). LUX meters are available in the market, which could be used by a lighting designer to measure the light falling on a given surface.

Repetitive Summary

The intensity of a light source is measured in candelas;
The total light flux in transit is measured in lumens (1 lumen = 1 candela X steradian);
The amount of light received per unit of surface area is measured in lux (1 lux = 1 lumen/square meter).

Having considered the various aspects related to lighting terminology, it is important to get an impression about the typical lighting levels that are common in day to day life, as shown in Tab.1.

Tab.1: Typical lighting levels in day to day life

Outdoor	Illuminance (lux)
Bright sun	50,000 – 100,000
Hazy day	10,000 – 50,000
Full moon	0.05 - 0.2
Indoor	Illuminance (lux)
Office or workshop	200 - 300
Reading Area	300 - 500
Class Room	300
Health Centres	Illuminance (lux)
Examination Area (Spot Light)	500
Surgery Room (Spot Light)	2000
Domestic Lighting	Illuminance (lux)
Living Room	100 - 300
Kitchen Working Area	300
Corridors	50 - 100
Good street light	20

Lighting Technologies

Artificial light is produced by the user at the expense of some energy and it can be classified as

flame-based lighting and
electricity-based lighting.

Flame-based Lighting

Flame-bases lighting is related to the production of light from fire. Burning of carbon-based fuels such as wood, kerosene, vegetable oil, gas, wax, etc., to produce light is based on the principle of ‘incandescence’. Incandescent lamps in general and flame-based lighting in particular are not very energy-efficient, as most energy is lost in the form of waste heat. Furthermore flame-based lighting results in the production of unwanted pollutants, which can be harmful to health.

Electricity-based Lighting

Lamps that produce light, using electricity have now become the standard for modern lighting. Existing lamps can be categorised as detailed below.

Incandescent Lamps

Incandescent lamps are based on the principle of incandescence, where a filament is heated to produce light, such as in standard tungsten filament lamps. Their energy efficiency is comparably low. For instance, when a typical 100 W incandescent lamp is lit, only about 10 W of energy is converted to visible light, the rest is converted to waste heat.An improved type, namely, the Halogen lamps are high pressure, incandescent lamps that consist of a tungsten filament inside a quartz envelope, which contains halogen gases such as iodine and bromine that allow filaments to work at higher temperatures and higher efficiencies.In halogen lamps, the quartz envelope is closer to the filament than the glass used in conventional light bulbs. Heating the filament to a high temperature causes the tungsten atoms to evaporate and combine with the halogen gas. These heavier molecules are then deposited back on the filament surface. This recycling process increases the life of the tungsten filament and enables the halogen lamp to produce more light per unit of energy. Consequently, halogen lamps are used in a variety of applications, including automobile headlights. Halogen lamps that work on both A.C. and D.C. power, ranging from 6 V to 230 V are available today. But usually, these lamps get very hot while in operation. They are sensitive to voltage fluctuations. Some studies indicate that their life expectancy is decreased to 50% by 5% overvoltage (e.g.: 0.6V on 12V) and by about 75% by 10% overvoltage.

Gas Discharge Lamps

Gas Discharge Lamps are based on a glowing gas in a glass enclosure. Examples for this type are sodium, mercury vapour and mercury tungsten (blended) lamps.In these lamps, the atoms or molecules of a gas inside a glass, quartz, or translucent ceramic tube, are ionized by an electric current sent through the gas or by a radio frequency or microwave field in proximity to the tube. This results in the generation of light - usually either visible or ultraviolet (UV). The colour depends on both the mixture of gasses and other materials inside the tube as well as the pressure and type and amount of the electric current or RF power (Radio-frequency power). There are a variety of gas discharge lamps, which are available in different forms, as explained further on.

Fluorescent Lamps

Fluorescent lamps are a special class of gas discharge lamps. Their functioning relies on the principle of fluorescence: Inside the glass tube is a partial vacuum and a small amount of mercury. An electric discharge in the tube causes the mercury atoms to emit light. The emitted light is in the ultraviolet range and is invisible, and also harmful to living organisms, so the tube is lined with a coating of a fluorescent (phosphoric) material, which absorbs the UVand re-emits visible light.They are sensitive to the ambient temperature around them. 1% loss in light output can be expected for every 2°F (1.1°C) above the optimum ambient temperature of 76°F (25°C), in most of the fluorescent lamps. But they are definitely more efficient than the incandescent lamps. Hum and flicker might be a problem in some cases. Frequent switching on and off will reduce the life of a fluorescent lamp.

Compact Fluorescent Lamps (CFLs)

A CFL can be seen as an advanced version of a fluorescent lamp. The salient features of it are: It consists of a gas-filled glass tube with two electrodes mounted in an end cap. It contains a low-pressure mix of argon gas, mercury vapour, and liquid mercury, and is coated on the inside with three different phosphorous substances. The electrodes provide a stream of electrons to the lamp and the ballast controls the current and voltage flowing into the assembly. The ballast, in general an electronic circuit, may be attached directly to the lamp, or may be remotely connected.CFLs are compact and are ideal for use in homes, work areas, schools, workshops, etc. They are more energy-efficient than incandescent light bulbs using between one third and one fifth of the energy. They are sensitive to the ambient temperatures, just like the standard fluorescent lamps.The life of a CFL is significantly shorter if it is used only for a few minutes at a time. Lab tests demonstrated that lifespan can be reduced down to 15% in the case of a 5 minute on/off cycle.

Low Pressure Sodium Lamps

A low pressure sodium lamp consists of a tube made of special sodium-resistant glass containing sodium and a neon-argon gas mixture. These lamps usually require 5 to 10 minutes to warm up. This light is basically monochromatic orange-yellow. This monochromatic light causes a dramatic lack of colour rendition: everything comes out in an orange-yellow version of black and white. Hence, low pressure sodium lamps are not suitable for use in homes, offices, workshops, etc. But they are widely used for street lighting purposes.Low pressure sodium lamps are the most energy efficient visible light sources in common use. These lamps have luminous efficacies as high as 180 lumens per Watt, whereas a typical incandescent lamp has around 12 lumens per Watt and a standard fluorescent lamp has around 45 lumens per Watt.

Light Emitting Diodes (LEDs)

Light Emitting Diodes (LEDs) are semiconductor devices similar to p-n junction diodes, specially engineered to emit visible light of a particular wavelength, giving out a specific colour.On supplying electrical power to an LED, electrons are made to “fall” from a high energy level to a low energy level inside the semiconductor material, releasing some energy, which is perceived as visible light.LEDs are usually monochromatic and are very energy-efficient and therefore used extensively as indicator lamps on many electronic devices. Red, green, and orange LEDs as indicator lamps are usually well known. They are usually operated with no more than 20 – 70 mW of electrical power and not adequate for lighting purposes. However, the development of bright white LEDs advanced rapidly in recent years and is achieving fast access to the market. In 1999, the first 1 W white LEDs came on the market. In 2002, first 5 W models were available.Parallel to this augmentation of the total power there has been also a dramatic increase in the luminous efficacies (see chapter 3.3) of LEDs during the past few years. Today the LEDs attain similar efficacy as CFLs and it is projected to increase further. In the last years, the price of bright white LEDs has fallen drastically and their availability increased considerably. Hence, LEDs are now used in many appliances like torches, bicycles and car lighting and are considered more and more for main stream lighting purposes.

LEDs have a longer life than the incandescent lamps and all types of gas discharge lamps. As they are solid-state devices, theoretically they offer operating periods of 100,000 to 150,000 hours. But they are the same time sensitive to ambient temperatures what caused some problems in first projects on LEDs as lighting devices in the tropics. A study by Lumitex Inc., U.S.A, indicates a substantial fall in the life of an LED, at elevated ambient temperatures (Fig. 4). Hence, special care must be taken to house LEDs properly, to ensure expected life. Life here implies, the time taken for the light output to fall to its 50% value, when compared to its initial light output.

Fig. 4: Relation between ambient temperatures and LED life

Relation between ambient temperatures and LED life

LEDs due to their construction emit light only in one direction and hence are more effective in task based or focussed lighting such as in table lamps, torch lights, etc.More information on LED lighting is provided in the Lighting Africa Briefing Note: Light Emitting Diode (LED) Lighting Basics.

Synopsis of Efficiency and Costs of Various Lighting Technologies

Having analysed the various technical factors governing the lighting technologies, both flame-based as well as electricity-based ones, it is now worthwhile to have a brief synopsis focussing on efficiency and costs of all the lighting technologies in a single table, as shown in Tab. 3. Some details are discussed in the following paragraphs.

Power of the Lighting Device

In tab. 3, the 3^rd column represents the power consumption of the lighting device. For flame based lighting systems, power of the device is calculated as shown here:

Power of the device (in Watts) =

Fuel consumption per second in litres or kgs X Energy Content of the fuel in Joules/litre or Joules/kg

The energy content of various fuels can be derived from tab. 2.
Tab. 2: Typical energy content of different fuels

Fuel	Energy Content (MJ/kg)
Wax	36.0
Kerosene	45
LPG	45
Biogas	27.7
Propane	42.5
Butane	43.3
Natural gas	46.4
Dry Wood	15

The fuel consumed by the lighting device in question per hour may be figured out by performing a test to find out the fuel consumed within 1 second.

The energy content of various fuels is the standard data provided by the research institutes, and may not be always available from the suppliers of fuels. Tab. 2 lists the typical values of the energy content of various fuels, expressed in mega joules per kg or litre (1 mega joule = 1000000 joules). If the fuel consumption is expressed in litres per second, then, the energy content should be expressed in joules per litre. If this is expressed in kg per second, the energy content of the fuel should be expressed in joules per kg.

Example: Power of the candle (as shown in Tab. 3)

The wax used = (0,0055 kg/hour), hence, wax used per second = 0,0055/3600 in kg.

The energy content of wax = 36 X 1000 000 joules.

Hence, the power consumption of the candle = (0,0055 /3600) X 36 X 1000 000 = 55 W

Example: Power of the kerosene lamp (as shown in Tab. 3)

The kerosene used = (0,03 lt/hour), hence, kerosene used per second = 0,03/3600 in kg.

The energy content of kerosene per litre = 36 X 1000 000 joules.

Hence, the power consumption of the kerosene lamp = (0,03 /3600) X 36 X 1000 000 = 300 W

Type of Lamps	Power'Consumption (W)'	Luminous Flux (lm)	Efficacy'Lm/W'	Life'(h)'	Typical Unit'[1]Price'(US $)	Annual Lamp/' Unit Costs'(1825 hrs/yr) (US $) (A)	Annual Maintenance Costs'(US $) (B)'	Annual Energy Costs'(US $)'(C)	Annual Operating Costs'(US $)'(A+B+C)	Annual Operating Costs (US $) (A+B+C)(Renewable Electricity[2])
Candle	55 - 72	1 - 16(10)	0.02 – 0.22	1	0,15	273,8	0	0	273,25	273,25
Kerosene/Oil(Wick:2.7 mm thick and 95 mm of inside diameter)	200 – 488(300)	10 –100(50)	0.05 – 0.21	5,500[3]	6,0	1,99	8 ($0.5 X 12 = wick + $1 X 2 = glass)	21,9 (0.03 ltr /hr @ $0.40 / ltr)	31,89	31,89
Liquified Petroleum Gas (LPG)	350 - 425	330 – 1000(750)	0.94 – 2.35	7,500[4]	20,0	4,867	8($0.5 X 12 = mantle+ $1 X 2 = glass)	27,375(30 gm /hr @ $0.50 / kg)	40,242	40,242
Incande-scent	100	1200	12	1,200	1,5	2,28	0	12,78 ( $0,07/ kWh)	15,06	40,62 ( $0,21/ kWh)
Halogen	25	500	20	2,000	6,5	5,931	0	3,194 ( $0,07/ kWh)	9,125	15,513 ( $0,21/ kWh)
Floures-cent(Ballast)26 mm tube diameter	18	750	45	8,000	17,0	3,878	0	2,30 ( $0,07/ kWh)	6,178	10,778 ( $0,21/ kWh)
Compact Floures-cent	5	280	56	9,000	8	1,622	0	0,638 ( $0,07/ kWh)	2,26	3,536 ( $0,21/ kWh)
LED (5mm)(WhiteUltra bright)	1	20	20	20,000[5]	10 - 15(12.5)	1,14	0	0,128 ( $0,07/ kWh)	1,268	1,524 ( $0,21/ kWh)

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[1] Unit price includes all the lamp accessories/fittings, together with the lamp cost.

[2] Usually the unelectrified remote villages might be supplied with electricity generated from renewable energy sources and in this case, the cost/kWh might be as high as $0.21.

[3] The wick and the glass may have to be changed very frequently, though the other parts might stand for so many hours.

[4] The mantle and a few parts may have to be changed frequently.

[5] The life of an LED may depend on how efficiently the lamp is enclosed. The rapid advances in LED technology, the life is projected to increase dramatically. Similarly the life of a CFL depends on the no. of times it is switched on/off. The life of a halogen lamp depends on voltage fluctuations, etc.

Luminous Performance or Efficacy

Luminous Performance is a measure of the efficiency of a device in converting electrical power to visible light and is measured in lumens/watt or lux/watt. As mentioned earlier, the low pressure sodium lamps have the highest luminous efficacy, followed by LEDs, fluorescents, and incandescents. Table 4 gives a comparative view of different lighting technologies.

Flame-based lighting has the worst luminous efficacy. A typical kerosene lamp with wick has a luminous efficacy of 0.1 lm/W and it is about 0.11 lm/W for a typical wax based candle. Kerosene pressure lamps might offer 1 to 2 lm/W and LPG (liquefied petroleum gas) lamps are a little better with about 1 to 2.5 lm/W, followed by biogas lamps that offer 0.5 to 0.9 lm/W. Also flame based lighting results in many other ill effects, causing indoor air pollution. Typical luminous efficacies for various lighting options are cited in Tab. 3.

Life of a Device

Life of a device is another important parameter to consider, while deciding on lighting technologies. Life of a lighting device is the number of total operating hours that the device can function satisfactorily. A wax candle of the type mentioned in Tab. 3 might last for an hour, while a typical kerosene lamp, shown in Tab. 3 might last for 5500 hours. Assuming the device to be used for 5 hours a day, this amounts to (5500/5 = 1100 days) or about 3 years of satisfactory operation of the kerosene/hurricane lamp.

Typical Unit Price

Usually, a lighting device is a unit complete with necessary accessories. While specifying lamp prices, it is better to consider unit prices rather than just the lamp prices. For instance, a kerosene lamp may have the frame, a glass chimney, a wick, etc. whereas an incandescent lamp may have a lamp holder. Fluorescent lamps use a frame, a starter, a ballast, besides the lamp. A CFL may have a ballast and a holder. An LED light system typically has a circuit board with some electronic components, besides the LED or LEDs.

As a lighting device is a total unit composing of these various components, it is always necessary to find out the total unit price. The prices are expressed in U.S. dollars for ease of use, as a standard unit of currency, in this document.

Annual Operating Costs

To take a sensible decision on choosing an appropriate lighting technology for a given situation, one of the most important criteria is the annual operating costs, which is the total amount of money one has to spend in one year to have the said benefits of lighting. The cost analysis is explained in the following chapter, in detail.

SCOPE – A Layman’s Approachfor Appropriate Lighting Design

Designing a lighting system appears complex and hence, it is better to have a systematic approach to arrive at a fair conclusion. Here, a simple practical approach to designing an optimum lighting system for a given setting is explained by five successive steps, namely, SCOPE. This approach might be adopted by any ordinary lighting designer aiming to provide adequate lighting for locations such as a house, health centre, school, streets, etc. The following paragraphs explain the approach in detail.

Specify the need
Consider the lighting options
Opt for an ideal lamp type
Preview the costs involved
End up deciding on an appropriate technology

Specify the Need

Firstly, it is important to specify the amount of light required. The lighting designer may consider the application – intended lighting area and decide on how much light is required for that situation. Tab.1 would assist in specifying the required amount of light in lux.

Consider the Lighting Options

In general, electricity-based lighting is the better option compared to flame-based lighting. But it is always possible to check on how much one has to spend in both of the cases, flame-based as well as electricity-based lighting options.

As discussed earlier in this document, lamps of different types have their respective luminous efficacies. Some of them are shown in Table. 4

To achieve the 300 lux required by the user, one may consider the following options for electricity-based lighting:

Incandescent Lamp:

Required light = 300 lux

Lamp’s Power = 100 W

Luminous efficacy of the lamp (from the Tab.4) = 12 lumens/Watt

Hence, the light output from the lamp =

Luminous efficacy X Lamp’s Power =

12 X 100 = 1200 lumens.

For instance, if the lamp is fixed on the roof or wall at a distance of about 2 metres from the surface to be illuminated, then, the total light falling on the surface to be illuminated is given by:

Light output from the lamp at source /

Square of the distance between the light source and the surface to be illuminated

Tab. 4: Luminous Efficacies of different lighting options

Type of Lamp	Luminous Efficacy (lm/W)
Flame Based Lamps
Kerosene Lantern	0.05 – 0.21
Kerosene Pressure Lamp	0.39 – 1.60
Candle (Wax)	0.02 – 0.22
Gas Lamp (LPG)	0.94 – 2.35
Biogas Lamp	0.48 – 0.94

Electricity Based Lamps
Incandescent Lamp (100 W)	12 - 15
Halogen Lamp (25 W)	20 - 30
Fluorescent Tube (13 W)	45 - 60
Fluorescent Lamp	56 - 60
Compact Fluorescent Lamp	50 - 90
Metal Halide	80 - 120
High Pressure Sodium	80 - 130
Low Pressure Sodium	90 - 220
Light Emitting Diode Lamps	25 - 150

In the above case, the total light falling on the surface to be illuminated would now be: 1200/2 sq.m = 1200/4 = 300 lumens. But these 300 lumens can be made to be concentrated on an area of 1 sq.m or more area. Luminaires (light concentrators) concentrate the light emitted by a lamp in the required direction. If a luminaire is used the light is distributed uniformly in the spectrum specified by the manufacturer. If - for instance - the area of the room is about 10 sq.m, then - without a luminaire - the amount of light falling on the surface to be illuminated in the current example would be: 300/10 = 30 lux.

As discussed, an incandescent lamp is the most inefficient of the electricity based lamp types, it may not be necessary to use a 100 W incandescent lamp with a luminaire to achieve the 300 lux mentioned in the current example.

It is indeed possible to consider various options to achieve the same results.

Side Note: Calculation of Luminous EfficacyLuminous efficacy is usually provided in the lamp specifications provided by the manufacturer in the case of electricity based lighting devices. In the case of flame based lighting devices, it might be helpful to follow the typical values suggested by the research institutes, as cited in Tab.4. However, some details are given in the following paragraphs to calibrate the luminous efficacies of both the electricity based as well as the flame based lighting technologies:

Calculation of Luminous Efficacy of an electricity based lighting device

If the power of luminous intensity of a lamp only is provided in candela (say for example, Φ cd), which is usually the case with most of the LED lamps, then, the following formula is applicable:

Light output in lumens: Luminous Intensity in candela X 4π ; (π ~ 3.14)

But it is important to note that the said amount of light output in lumens would be confined to the dispersion region specified for a lamp type. If it is an incandescent lamp, the total light output is equally distributed around the bulb (360° dispersion angle). In the case of fluorescents it might be a 180° dispersion angle. Whereas in the case of LED lamps, the light output might be confined to a very narrow beam of a dispersion angles ranging from 5°;to 180°. It can be seen from this that it is not possible to compare the overall lighting effect from lamps of different characteristics. If, for instance, an LED lamp provides light output in a narrow beam of 30° dispersion angle, then one may have to arrange about 6 LEDs in different positions to achieve 180° of total dispersion angle. But it is also possible to buy LEDs of 180° dispersion angle, where the light output is equally distributed around the lamp.

It must be noted here that all the luminous flux in lumens and the luminous intenstiy in candela disscussed here holds good for a (lamp to lighting area) distance of one metre. If the distance is different from this, it is possible to calculate the light output at the given position, using the following formula:

Light Intensity at source: Φ (cd)

Light intensity at a distance of ‘d’ metres away from the light source = Φ/d^2(cd)

Calculation of Luminous Efficacy of a flame based lighting device

If the luminous efficacies are not specified by the manufacturer, which is usually the case with flame based lighting options, it might be possible to use the following procedure to find out the same:

Amount of fuel (kerosene, gas) consumed by the lamp per hour = δ kg.Energy content of the fuel (kerosene) = 10 kWh per litre (or 12.5 kWh per kg)Energy content of the fuel (gas) = 12.5 kWh per kg.

[Also, it is possible to use the values from Table.3: (Energy content of a fuel in kWh = Energy content of the fuel in MJ / 3.6).]

Hence, the Power consumption/hour (in kilowatts or kW). = Energy content in kWh X δ

The amount of light output may be found out by using a standard LUX meter at the intended spot or area. Now, the luminous efficacy may be found out as shown here:

Luminous Efficacy (lm/W) =

Measured Illumination in Lux / Power consumption of the lamp in Watts

LUX meter can also be utilised to measure the illumination on a specified area from electricity based light sources, and thus calculate their luminous efficacies, using the same formula shown above.

To have a more generalised approach to obtain the required lighting levels, one may consider the following approach. (The letters in perenthesis are symbols):

(a) Power of the Lamp (S) in Watts

(b) Luminous efficacy (T) in lm/W

(c) Light flux or light output from the lamp = S X T in lumens

(d) Total surface area on which the light is falling is say, U sq.m,

(e) Light illumination on a given surface at 1 metre from the source = S X T/ U in lux.

(f)Light illumination on a given surface at ‘d’ metres from the source = (S X T)/(d²)(U) in lux.

As lamps of a given wattage are available, it is possible to determine the exact amount of lighting that would reach the surface to be illuminated, with the lamp type considered using the procedure mentioned. If more illumination is required, then, it is necessary to consider the lamp types of higher power (or wattage) rating or consider a luminaire or a concentrator for the lamp. However, it is always possible to check the level of illumination on a given surface, simply by using a LUX meter.

Opt for an Ideal Lamp Type

Based on the procedures mentioned in the preceding paragraphs, it is easier to decide on a lamp type for a given situation. However, it should be noted that some lamps are best suited for certain applications.As a rule, fluorescents might be ideal for use in homes, work areas while Halogen lamps and LED based lamps might be ideal for focussed, task based lighting. Low pressure sodium lamps may be considered for parking areas. It is better to avoid the incandescent lamps as much as possible. It is also important to look at the availability of the lamp types in the market, for easy replacement.

Comparison of CFLs and LEDs

Both technologies are quite new, have similar efficacy and hence are the most important lighting technologies for projects that provide modern lighting services to the poor. Therefore the main differences are to be described.

Their efficacy (input of electrical power / light output) is similar.

LEDs are generally available as smaller units with less power. Typical characteristic values of CFLs are 5 to 11 W. Typical LEDs have 1- 5 W. Therefore – today - LEDs qualify for smaller application units.

In contrast to CFLs the LEDs emit light only in one direction and hence are more effective in task based or focussed lighting such as in table lamps, torch lights, etc.

For instance, a 0.3 W LED that delivers a luminous flux of only 10 lumens, which is only about 3.5% of the 280 lumens, delivered by a 5 W CFL, can offer double the illuminance (in lux) on a table or a book, when compared to the 5 W CFL.

CFLs are not suitable for use with frequently switching on and off.

The lower power requirements, higher durability and rapid advancements, are projected to offer competitive long-term operating costs, making LED technology more attractive for lighting solutions in the developing world.

Preview the Costs Involved

Having considered various selection criteria for different technologies, it is important to have a preview of the costs involved in considering a specific option. It would be of advantage to calculate the total operating costs for one full year, for each lighting option, which would reflect the cost of the lamp, cost of energy, cost of labour and maintenance, as shown in Tab. 5 (see attached excel calculation sheet).Tab. 5 serves as a guide with some typical lighting options, based on realistic values of the various specifications. The ultimate aim of Tab. 5 is to compute the annual operating costs of a lamp type.

Total Annual Operating Costs =

Lamp/Unit Costs / Year +

Maintenance Costs / Year +

Electricity/Energy Costs/ Year

Lamp/Unit costs / Year: This is the amount spent on lamp units per year. Depending on the life of a lamp/Unit, the costs differ from lamp type to type. (Tab.5, No.12)
Maintenance costs / Year: It is the amount spent on the lamp/unit, excluding the energy costs. In case of flame based lighting, this would mean the amount spent on wicks, glass cover, etc. In case of electricity based lighting, this might mean the lamp replacement cost, etc. (Tab.5, No.13)
Electricity/Energy costs/ Year: It is the amount spent on energy consumed by the lighting device/unit in consideration in a year. (Tab.5, No.14)

To compute these three major components (a, b & c) that constitute the total operating costs per year, the following data has to be obtained from reliable sources for the lighting options considered:

For flame based as well as electricity based lighting options:

1.'Lamp/Unit Cost = (A) ($)

2.'Lamp Life in hours = (B)

3.'Lamp Operating hours/day = (C)

4.'Lamp Maintenance Cost/Year = (D) ($)

5.'Total Number of Lamps used = (E)

Only for Flame based lighting options:

6.'Average Fuel Cost /kg = (I) ($)

7.'Fuel Consumption/ hour/lamp = (J) kg

Only for Electricity based lighting options:

8.'Lamp Power = (F) Watts

9.'Average Electricity Cost /kWh = (G) ($)

Once these values are entered into their respective columns in Table.5, then, the total annual operating costs of a lamp type are computed automatically.

10.''Lamp/Unit Costs / Year (P)= (A X C X 365 X E)/ (B)

11. 'Lamp Maintenance Cost/ Year (Q) ($):

For instance, the kerosene lamp considered consumes one wick every month. Assuming the cost of a wick to be $ 0.50, the total amount spent on wicks in a year would be ($ 0.50 X 12 = $ 6). Also, assuming the cost of the glass cover to be $ 1, when the glass cover is to be replaced once in 6 months, then the total annual maintenance costs would be ($ 6 + $ 2 = $ 8). In the case of electricity based lighting options, some lamp replacement costs might apply, if the lamps are to be replaced in a public building, where an electrician is employed.

12. 'Electricity/Energy Costs/ Year

Energy costs are the most important recurring costs, which would increase with increasing load or with increasing power of the lamp in consideration.

For Flame based lighting systems,

Total Energy Cost / Year in ($) (J) =

(I X J X C X E X 365)

[(J) = (average fuel cost/kg X Fuel consumption/hour/lamp X Lamp operating hours per day X number of lamps used X 365 days) ].

For Electricity based lighting systems,

Total Electricity Cost / Year in ($) (H) =

(F X C X G X E X 365)/1000

[ (H) = (Lamp power in watts X lamp operating hours/day X Average electricity cost/kWh X Total number of lamps used X 365 days)/ 1000].

Some examples are shown in Tab. 5

Summary: End Up Deciding on an Appropriate Lighting Method

To summarise the steps explained in the previous sections:

define the need.
check what lighting options may or may not be considered looking at the light output and the general characteristics of the lamp in consideration, as well as the intended application, making sure that the lamp unit is affordable and spare parts are available in the local market/vicinity, for the initial investment.
calculate the total operating costs of the lamp/unit per year, for the lamp type in consideration.
calculate how much light output can be expected and how much would it cost the user.
select the most suitable lamp type (if a gas lamp appears economical to a comparable electric lamp option, it would be good to choose the electric lamp, as there is no air pollution associated with the latter).

After deciding on the lamp type it would be helpful to list the parameters with the data obtained, as shown here:

Amount of light considered
Target Application area
Source of Energy considered
Lamp type considered
Price/kWh of electricity or Price/litre or kg of fuel considered
Price of lighting obtained/Operating costs per one year.
Initial investment required for the lighting option.

Further Information

References

@@ Line 1: / Line 1: @@
-= Overview  =
+= Overview =
 <u>A short overview of the terminology:</u>
+<br/>
 == Luminous Intensity<br/> ==
-<div class="mw-collapsible mw-collapsed">Luminous intensity is a measure of the amount of light originated from the source, its light output, the unit of which is the '''''candela (cd)'''''.
+<div class="mw-collapsible mw-collapsed">Luminous intensity is a measure of the amount of light originated from the source, its light output, the unit of which is the '''''candela (cd)'''''.<br/><br/>
-<br/>
@@ Line 57: / Line 55: @@
 |-
 | style="width: 59%;  background-color: rgb(204, 204, 204)" | '''Outdoor'''
 | style="width: 40%;  background-color: rgb(204, 204, 204)" | '''Illuminance (lux)'''
 |-
 | style="width: 59%" | Bright sun
 | style="width: 40%" | 50,000 – 100,000
 |-
 | style="width: 59%" | Hazy day
 | style="width: 40%" | 10,000 – 50,000
 |-
 | style="width: 59%" | Full moon
 | style="width: 40%" | 0.05 - 0.2
 |-
 | style="width: 59%;  background-color: rgb(204, 204, 204)" | '''Indoor'''
 | style="width: 40%;  background-color: rgb(204, 204, 204)" | '''Illuminance (lux)'''
 |-
 | style="width: 59%" | Office or workshop
 | style="width: 40%" | 200 - 300
 |-
 | style="width: 59%" | Reading Area
 | style="width: 40%" | 300 - 500
 |-
 | style="width: 59%" | Class Room
 | style="width: 40%" | 300
 |-
 | style="width: 59%;  background-color: rgb(204, 204, 204)" | '''Health Centres'''
 | style="width: 40%;  background-color: rgb(204, 204, 204)" | '''Illuminance (lux)'''
 |-
 | style="width: 59%" | Examination Area (Spot Light)
 | style="width: 40%" | <font size="2">500</font>
 |-
 | style="width: 59%" | Surgery Room (Spot Light)
 | style="width: 40%" | 2000
 |-
 | style="width: 59%;  background-color: rgb(204, 204, 204)" | '''Domestic Lighting'''
 | style="width: 40%;  background-color: rgb(204, 204, 204)" | '''Illuminance (lux)'''
 |-
 | style="width: 59%" | Living Room
 | style="width: 40%" | 100 - 300
 |-
 | style="width: 59%" | Kitchen Working Area
 | style="width: 40%" | 300
 |-
 | style="width: 59%" | Corridors
 | style="width: 40%" | 50 - 100
 |-
 | style="width: 59%" | Good street light
 | style="width: 40%" | 20
 |}
-</div><br/>
+</div><br/><br/>
 </div>
 = Lighting Technologies<br/> =
-<div class="mw-collapsible mw-collapsed">Artificial light is produced by the user at the expense of some energy and it can be classified as
+<div class="mw-collapsible mw-collapsed"><u>Artificial light is produced by the user at the expense of some energy and it can be classified as</u>
+#flame-based lighting and
+#electricity-based lighting.
+<br/>
+</div>
-#flame-based lighting and
-#electricity-based lighting.
-<br/></div>
 == Flame-based Lighting ==
-<div class="mw-collapsible mw-collapsed">Flame-bases lighting is related to the production of light from fire. Burning of carbon-based fuels such as wood, kerosene, vegetable oil, gas, wax, etc., to produce light is based on the principle of ''‘incandescence’''. Incandescent lamps in general and flame-based lighting in particular are not very energy-efficient, as most energy is lost in the form of waste heat. Furthermore flame-based lighting results in the production of unwanted pollutants, which can be harmful to health.
+<div class="mw-collapsible mw-collapsed">Flame-bases lighting is related to the production of light from fire. Burning of carbon-based fuels such as wood, kerosene, vegetable oil, gas, wax, etc., to produce light is based on the principle of ''‘incandescence’''. Incandescent lamps in general and flame-based lighting in particular are not very energy-efficient, as most energy is lost in the form of waste heat. Furthermore flame-based lighting results in the production of unwanted pollutants, which can be harmful to health.<br/></div><div class="mw-collapsible mw-collapsed"></div><div class="mw-collapsible mw-collapsed"></div>
-<br/></div>
 == Electricity-based Lighting<br/> ==
-<div class="mw-collapsible mw-collapsed">Lamps that produce light, using electricity have now become the standard for modern lighting. Existing lamps can be categorised as detailed below.
+<div class="mw-collapsible mw-collapsed">Lamps that produce light, using electricity have now become the standard for modern lighting. Existing lamps can be categorised as detailed below.<br/></div><div class="mw-collapsible mw-collapsed"></div><div class="mw-collapsible mw-collapsed"></div>
-<br/></div>
 === Incandescent Lamps<br/> ===
-<div class="mw-collapsible mw-collapsed">Incandescent lamps are based on the principle of incandescence, where a filament is heated to produce light, such as in standard tungsten filament lamps. Their energy efficiency is comparably low. For instance, when a typical 100 W incandescent lamp is lit, only about 10 W of energy is converted to visible light, the rest is converted to waste heat.
+<div class="mw-collapsible mw-collapsed">Incandescent lamps are based on the principle of incandescence, where a filament is heated to produce light, such as in standard tungsten filament lamps. Their energy efficiency is comparably low. For instance, when a typical 100 W incandescent lamp is lit, only about 10 W of energy is converted to visible light, the rest is converted to waste heat.An improved type, namely, the Halogen lamps are high pressure, incandescent lamps that consist of a tungsten filament inside a quartz envelope, which contains halogen gases such as iodine and bromine that allow filaments to work at higher temperatures and higher efficiencies.In halogen lamps, the quartz envelope is closer to the filament than the glass used in conventional light bulbs. Heating the filament to a high temperature causes the tungsten atoms to evaporate and combine with the halogen gas. These heavier molecules are then deposited back on the filament surface. This recycling process increases the life of the tungsten filament and enables the halogen lamp to produce more light per unit of energy. Consequently, halogen lamps are used in a variety of applications, including automobile headlights. Halogen lamps that work on both A.C. and D.C. power, ranging from 6 V to 230 V are available today. But usually, these lamps get very hot while in operation. They are sensitive to voltage fluctuations. Some studies indicate that their life expectancy is decreased to 50% by 5% overvoltage (e.g.: 0.6V on 12V) and by about 75% by 10% overvoltage.
-An improved type, namely, the Halogen lamps are high pressure, incandescent lamps that consist of a tungsten filament inside a quartz envelope, which contains halogen gases such as iodine and bromine that allow filaments to work at higher temperatures and higher efficiencies.
-In halogen lamps, the quartz envelope is closer to the filament than the glass used in conventional light bulbs. Heating the filament to a high temperature causes the tungsten atoms to evaporate and combine with the halogen gas. These heavier molecules are then deposited back on the filament surface. This recycling process increases the life of the tungsten filament and enables the halogen lamp to produce more light per unit of energy. Consequently, halogen lamps are used in a variety of applications, including automobile headlights. Halogen lamps that work on both A.C. and D.C. power, ranging from 6 V to 230 V are available today. But usually, these lamps get very hot while in operation. They are sensitive to voltage fluctuations. Some studies indicate that their life expectancy is decreased to 50% by 5% overvoltage (e.g.: 0.6V on 12V) and by about 75% by 10% overvoltage.
 <br/></div>
 === Gas Discharge Lamps<br/> ===
-<div class="mw-collapsible mw-collapsed">Gas Discharge Lamps are based on a glowing gas in a glass enclosure. Examples for this type are sodium, mercury vapour and mercury tungsten (blended) lamps.
+<div class="mw-collapsible mw-collapsed">Gas Discharge Lamps are based on a glowing gas in a glass enclosure. Examples for this type are sodium, mercury vapour and mercury tungsten (blended) lamps.In these lamps, the atoms or molecules of a gas inside a glass, quartz, or translucent ceramic tube, are ionized by an electric current sent through the gas or by a radio frequency or microwave field in proximity to the tube. This results in the generation of light - usually either visible or ultraviolet (UV). The colour depends on both the mixture of gasses and other materials inside the tube as well as the pressure and type and amount of the electric current or RF power (Radio-frequency power). There are a variety of gas discharge lamps, which are available in different forms, as explained further on.<br/></div><div class="mw-collapsible mw-collapsed"></div>
-In these lamps, the atoms or molecules of a gas inside a glass, quartz, or translucent ceramic tube, are ionized by an electric current sent through the gas or by a radio frequency or microwave field in proximity to the tube. This results in the generation of light - usually either visible or ultraviolet (UV). The colour depends on both the mixture of gasses and other materials inside the tube as well as the pressure and type and amount of the electric current or RF power (Radio-frequency power). There are a variety of gas discharge lamps, which are available in different forms, as explained further on.
-<br/></div>
 ==== Fluorescent Lamps<br/> ====
-<div class="mw-collapsible mw-collapsed">Fluorescent lamps are a special class of gas discharge lamps. Their functioning relies on the <span>principle of fluorescence: Inside the glass tube is a partial vacuum and a small amount of mercury. An electric discharge in the tube causes the mercury atoms to emit light. The emitted light is in the ultraviolet range and is invisible, and also harmful to living organisms, so the tube is lined with a coating of a fluorescent (phosphoric) material, which absorbs the </span>UV<span>and re-emits visible light.</span>
+<div class="mw-collapsible mw-collapsed">Fluorescent lamps are a special class of gas discharge lamps. Their functioning relies on the <span>principle of fluorescence: Inside the glass tube is a partial vacuum and a small amount of mercury. An electric discharge in the tube causes the mercury atoms to emit light. The emitted light is in the ultraviolet range and is invisible, and also harmful to living organisms, so the tube is lined with a coating of a fluorescent (phosphoric) material, which absorbs the </span>UV<span>and re-emits visible light.</span><span>They are sensitive to the ambient temperature around them. 1% loss in light output can be expected for every 2°F (1.1°C) above the optimum ambient temperature of 76°F (25°C), in most of the fluorescent lamps. But they are definitely more efficient than the incandescent lamps. </span>Hum and flicker might be a problem in some cases. Frequent switching on and off will reduce the life of a fluorescent lamp.<br/></div><div class="mw-collapsible mw-collapsed"></div>
-<span>They are sensitive to the ambient temperature around them. 1% loss in light output can be expected for every 2°F (1.1°C) above the optimum ambient temperature of 76°F (25°C), in most of the fluorescent lamps. But they are definitely more efficient than the incandescent lamps. </span>Hum and flicker might be a problem in some cases. Frequent switching on and off will reduce the life of a fluorescent lamp.
-<br/></div>
 ==== Compact Fluorescent Lamps (CFLs)<br/> ====
-<div class="mw-collapsible mw-collapsed">A CFL can be seen as an advanced version of a fluorescent lamp. The salient features of it are: It consists of a gas-filled glass tube with two electrodes mounted in an end cap. It contains a low-pressure mix of argon gas, mercury vapour, and liquid mercury, and is coated on the inside with three different phosphorous substances. The electrodes provide a stream of electrons to the lamp and the ballast controls the current and voltage flowing into the assembly. The ballast, in general an electronic circuit, may be attached directly to the lamp, or may be remotely connected.
+<div class="mw-collapsible mw-collapsed">A CFL can be seen as an advanced version of a fluorescent lamp. The salient features of it are: It consists of a gas-filled glass tube with two electrodes mounted in an end cap. It contains a low-pressure mix of argon gas, mercury vapour, and liquid mercury, and is coated on the inside with three different phosphorous substances. The electrodes provide a stream of electrons to the lamp and the ballast controls the current and voltage flowing into the assembly. The ballast, in general an electronic circuit, may be attached directly to the lamp, or may be remotely connected.CFLs are compact and are ideal for use in homes, work areas, schools, workshops, etc. They are more energy-efficient than incandescent light bulbs using between one third and one fifth of the energy. They are sensitive to the ambient temperatures, just like the standard fluorescent lamps.The life of a CFL is significantly shorter if it is used only for a few minutes at a time. Lab tests demonstrated that lifespan can be reduced down to 15% in the case of a 5 minute on/off cycle.
-CFLs are compact and are ideal for use in homes, work areas, schools, workshops, etc. They are more energy-efficient than incandescent light bulbs using between one third and one fifth of the energy. They are sensitive to the ambient temperatures, just like the standard fluorescent lamps.
-The life of a CFL is significantly shorter if it is used only for a few minutes at a time. Lab tests demonstrated that lifespan can be reduced down to 15% in the case of a 5 minute on/off cycle.
 <br/></div>
 ==== Low Pressure Sodium Lamps<br/> ====
-<div class="mw-collapsible mw-collapsed">A low pressure sodium lamp consists of a tube made of special sodium-resistant glass containing sodium and a neon-argon gas mixture. These lamps usually require 5 to 10 minutes to warm up. This light is basically monochromatic orange-yellow. This monochromatic light causes a dramatic lack of colour rendition: everything comes out in an orange-yellow version of black and white. Hence, low pressure sodium lamps are not suitable for use in homes, offices, workshops, etc. But they are widely used for street lighting purposes.
+<div class="mw-collapsible mw-collapsed">A low pressure sodium lamp consists of a tube made of special sodium-resistant glass containing sodium and a neon-argon gas mixture. These lamps usually require 5 to 10 minutes to warm up. This light is basically monochromatic orange-yellow. This monochromatic light causes a dramatic lack of colour rendition: everything comes out in an orange-yellow version of black and white. Hence, low pressure sodium lamps are not suitable for use in homes, offices, workshops, etc. But they are widely used for street lighting purposes.Low pressure sodium lamps are the most energy efficient visible light sources in common use. These lamps have luminous efficacies as high as 180 lumens per Watt, whereas a typical incandescent lamp has around 12 lumens per Watt and a standard fluorescent lamp has around 45 lumens per Watt.<br/></div><div class="mw-collapsible mw-collapsed"></div>
-Low pressure sodium lamps are the most energy efficient visible light sources in common use. These lamps have luminous efficacies as high as 180 lumens per Watt, whereas a typical incandescent lamp has around 12 lumens per Watt and a standard fluorescent lamp has around 45 lumens per Watt.
-<br/></div>
 === Light Emitting Diodes (LEDs)<br/> ===
-<div class="mw-collapsible mw-collapsed">[[Light_Emitting_Diode_(LED)|Light Emitting Diodes (LEDs)]] are semiconductor devices similar to p-n junction diodes, specially engineered to emit visible light of a particular wavelength, giving out a specific colour.On supplying electrical power to an LED, electrons are made to “fall” from a high energy level to a low energy level inside the semiconductor material, releasing some energy, which is perceived as <span>visible light.</span>
+<div class="mw-collapsible mw-collapsed">[[Light Emitting Diode (LED)|Light Emitting Diodes (LEDs)]] are semiconductor devices similar to p-n junction diodes, specially engineered to emit visible light of a particular wavelength, giving out a specific colour.On supplying electrical power to an LED, electrons are made to “fall” from a high energy level to a low energy level inside the semiconductor material, releasing some energy, which is perceived as <span>visible light.</span>LEDs are usually monochromatic and are very energy-efficient and therefore used extensively as indicator lamps on many electronic devices. Red, green, and orange LEDs as indicator lamps are usually well known. They are usually operated with no more than 20 – 70 mW of electrical power and not adequate for lighting purposes. However, the development of bright white LEDs advanced rapidly in recent years and is achieving fast access to the market. In 1999, the first 1 W white LEDs came on the market. In 2002, first 5 W models were available.Parallel to this augmentation of the total power there has been also a dramatic increase in the luminous efficacies (see chapter 3.3) of LEDs during the past few years. Today the LEDs attain similar efficacy as CFLs and it is projected to increase further. In the last years, the price of bright white LEDs has fallen drastically and their availability increased considerably. Hence, LEDs are now used in many appliances like torches, bicycles and car lighting and are considered more and more for main stream lighting purposes.
-LEDs are usually monochromatic and are very energy-efficient and therefore used extensively as indicator lamps on many electronic devices. Red, green, and orange LEDs as indicator lamps are usually well known. They are usually operated with no more than 20 – 70 mW of electrical power and not adequate for lighting purposes. However, the development of bright white LEDs advanced rapidly in recent years and is achieving fast access to the market. In 1999, the first 1 W white LEDs came on the market. In 2002, first 5 W models were available.
-Parallel to this augmentation of the total power there has been also a dramatic increase in the luminous efficacies (see chapter 3.3) of LEDs during the past few years. Today the LEDs attain similar efficacy as CFLs and it is projected to increase further. In the last years, the price of bright white LEDs has fallen drastically and their availability increased considerably. Hence, LEDs are now used in many appliances like torches, bicycles and car lighting and are considered more and more for main stream lighting purposes.
 LEDs have a longer life than the incandescent lamps and all types of gas discharge lamps. As they are solid-state devices, theoretically they offer operating periods of 100,000 to 150,000 hours. But they are the same time sensitive to ambient temperatures what caused some problems in first projects on LEDs as lighting devices in the tropics. A study by Lumitex Inc., U.S.A, indicates a substantial fall in the life of an LED, at elevated ambient temperatures (Fig. 4). Hence, special care must be taken to house LEDs properly, to ensure expected life. Life here implies, the time taken for the light output to fall to its 50% value, when compared to its initial light output.
@@ Line 200: / Line 137: @@
 <br/>
-<p style="text-align: center">''Fig. 4: Relation between ambient temperatures and LED life''</p>[[File:LED life.png|thumb|center|305px|Relation between ambient temperatures and LED life]]<br/>
+<p style="text-align: center">''Fig. 4: Relation between ambient temperatures and LED life''</p>[[File:LED life.png|thumb|center|305px|Relation between ambient temperatures and LED life]]<br/>LEDs due to their construction emit light only in one direction and hence are more effective in task based or focussed lighting such as in table lamps, torch lights, etc.More information on LED lighting is provided in the [http://www.lightingafrica.org/files/Lighting_Africa_Briefing_Notes_21.Dec_.2009.pdf Lighting Africa Briefing Note: Light Emitting Diode (LED) Lighting Basics].
-LEDs due to their construction emit light only in one direction and hence are more effective in task based or focussed lighting such as in table lamps, torch lights, etc.
-More information on LED lighting is provided in the [http://www.lightingafrica.org/files/Lighting_Africa_Briefing_Notes_21.Dec_.2009.pdf Lighting Africa Briefing Note: Light Emitting Diode (LED) Lighting Basics].
 <br/></div>
 = Synopsis of Efficiency and Costs of Various Lighting Technologies<br/> =
-<div class="mw-collapsible mw-collapsed">Having analysed the various technical factors governing the lighting technologies, both flame-based as well as electricity-based ones, it is now worthwhile to have a brief synopsis focussing on efficiency and costs of all the lighting technologies in a single table, as shown in Tab. 3. Some details are discussed in the following paragraphs.
+<div class="mw-collapsible mw-collapsed">Having analysed the various technical factors governing the lighting technologies, both flame-based as well as electricity-based ones, it is now worthwhile to have a brief synopsis focussing on efficiency and costs of all the lighting technologies in a single table, as shown in Tab. 3. Some details are discussed in the following paragraphs.<br/><br/>
-<br/>
@@ Line 218: / Line 147: @@
 In tab. 3, the 3<sup>rd</sup> column represents the power consumption of the lighting device. For flame based lighting systems, power of the device is calculated as shown here:
-<p style="text-align: center"><br/>''Power of the device (in Watts) =''</p><p style="text-align: center">''Fuel consumption per second in litres or kgs X Energy Content of the fuel in Joules/litre or Joules/kg''</p><br/>The energy content of various fuels can be derived from tab. 2.
+<p style="text-align: center"><br/>''Power of the device (in Watts) =''</p><p style="text-align: center">''Fuel consumption per second in litres or kgs X Energy Content of the fuel in Joules/litre or Joules/kg''</p><br/>The energy content of various fuels can be derived from tab. 2.<br/>''Tab. 2: Typical energy content of different fuels''
-<br/>
-''Tab. 2: Typical energy content of different fuels''
 {| cellspacing="0" cellpadding="0" border="1" style="width: 100%"
 |-
-| style="vertical-align: top;  width: 96px;  background-color: rgb(204, 204, 204)" | '''Fuel'''<br/>
+| style="vertical-align: top;  width: 96px;  background-color: rgb(204, 204, 204)" | '''Fuel'''
+| style="vertical-align: top;  width: 96px;  background-color: rgb(204, 204, 204)" | '''Energy Content (MJ/kg)'''
-| style="vertical-align: top;  width: 96px;  background-color: rgb(204, 204, 204)" | '''Energy Content (MJ/kg)'''<br/>
 |-
 | style="vertical-align: top;  width: 96px" | Wax
 | style="vertical-align: top;  width: 96px" | 36.0
 |-
 | style="vertical-align: top;  width: 96px" | Kerosene
 | style="vertical-align: top;  width: 96px" | 45
 |-
 | style="vertical-align: top;  width: 96px" | LPG
 | style="vertical-align: top;  width: 96px" | 45
 |-
 | style="vertical-align: top;  width: 96px" | Biogas
 | style="vertical-align: top;  width: 96px" | 27.7
 |-
 | style="vertical-align: top;  width: 96px" | Propane
 | style="vertical-align: top;  width: 96px" | 42.5
 |-
 | style="vertical-align: top;  width: 96px" | Butane
 | style="vertical-align: top;  width: 96px" | 43.3
 |-
 | style="vertical-align: top;  width: 96px" | Natural gas
 | style="vertical-align: top;  width: 96px" | 46.4
 |-
 | style="vertical-align: top;  width: 96px" | Dry Wood
 | style="vertical-align: top;  width: 96px" | 15
 |}
 <br/>
@@ Line 304: / Line 211: @@
 |-
 | style="vertical-align: top;  width: 91px;  background-color: rgb(204, 204, 204)" | '''Type of Lamps'''
+| style="vertical-align: top;  width: 69px;  background-color: rgb(204, 204, 204)" | '''Power''''''Consumption (W)'''
-| style="vertical-align: top;  width: 69px;  background-color: rgb(204, 204, 204)" | '''Power'''
-'''Consumption (W)'''
 | style="vertical-align: top;  width: 81px;  background-color: rgb(204, 204, 204)" | '''Luminous Flux (lm)'''
+| style="vertical-align: top;  width: 77px;  background-color: rgb(204, 204, 204)" | '''Efficacy''''''Lm/W'''
+| style="vertical-align: top;  width: 56px;  background-color: rgb(204, 204, 204)" | '''Life''''''(h)'''
+| style="vertical-align: top;  width: 57px;  background-color: rgb(204, 204, 204)" | '''Typical Unit'''[1]'''Price''''''(US $)'''
-| style="vertical-align: top;  width: 77px;  background-color: rgb(204, 204, 204)" | '''Efficacy'''
+| style="vertical-align: top;  width: 91px;  background-color: rgb(204, 204, 204)" | '''Annual Lamp/'''<br/>'''Unit Costs''''''(1825 hrs/yr)'''
-'''Lm/W'''
-| style="vertical-align: top;  width: 56px;  background-color: rgb(204, 204, 204)" | '''Life'''
-'''(h)'''
-| style="vertical-align: top;  width: 57px;  background-color: rgb(204, 204, 204)" | '''Typical Unit'''[1]
-'''Price'''
-'''(US $)'''
-| style="vertical-align: top;  width: 91px;  background-color: rgb(204, 204, 204)" | '''Annual Lamp/'''<br/>
-'''Unit Costs'''
-'''(1825 hrs/yr)'''
 '''(US $) (A)'''
-| style="vertical-align: top;  width: 106px;  background-color: rgb(204, 204, 204)" | '''Annual Maintenance Costs'''
+| style="vertical-align: top;  width: 106px;  background-color: rgb(204, 204, 204)" | '''Annual Maintenance Costs''''''(US $) (B)'''
+| style="vertical-align: top;  width: 76px;  background-color: rgb(204, 204, 204)" | '''Annual Energy Costs''''''(US $)''''''(C)'''
-'''(US $) (B)'''
+| style="vertical-align: top;  width: 76px;  background-color: rgb(204, 204, 204)" | '''Annual Operating Costs''''''(US $)''''''(A+B+C)'''
-| style="vertical-align: top;  width: 76px;  background-color: rgb(204, 204, 204)" | '''Annual Energy Costs'''
+| style="vertical-align: top;  width: 114px;  background-color: rgb(204, 204, 204)" | '''Annual '''<br/>'''Operating'''<br/>'''Costs'''
-'''(US $)'''
-'''(C)'''
-| style="vertical-align: top;  width: 76px;  background-color: rgb(204, 204, 204)" | '''Annual Operating Costs'''
-'''(US $)'''
-'''(A+B+C)'''
-| style="vertical-align: top;  width: 114px;  background-color: rgb(204, 204, 204)" | '''Annual '''<br/>
-'''Operating'''<br/>
-'''Costs'''
 '''(US $)'''
@@ Line 363: / Line 236: @@
 |-
 | style="vertical-align: top;  width: 91px" | Candle
-<br/>
 | style="vertical-align: top;  width: 69px" | 55 - 72
+| style="vertical-align: top;  width: 81px" | 1 - 16(10)
-| style="vertical-align: top;  width: 81px" | 1 - 16
-(10)
 | style="vertical-align: top;  width: 77px" | 0.02 – 0.22
 | style="vertical-align: top;  width: 56px" | <font size="2">1</font>
 | style="vertical-align: top;  width: 57px" | 0,15
 | style="vertical-align: top;  width: 91px" | 273,8
 | style="vertical-align: top;  width: 106px" | 0
 | style="vertical-align: top;  width: 76px" | 0
 | style="vertical-align: top;  width: 76px" | 273,25
 | style="vertical-align: top;  width: 114px" | 273,25
 |-
-| style="vertical-align: top;  width: 91px" | Kerosene/
+| style="vertical-align: top;  width: 91px" | Kerosene/Oil(Wick:2.7 mm thick and 95 mm of inside diameter)
-Oil
-(Wick:2.7 mm thick and 95 mm of inside diameter)
-| style="vertical-align: top;  width: 69px" | 200 – 488
-(300)
-| style="vertical-align: top;  width: 81px" | 10 –100
-(50)
+| style="vertical-align: top;  width: 69px" | 200 – 488(300)
+| style="vertical-align: top;  width: 81px" | 10 –100(50)
 | style="vertical-align: top;  width: 77px" | 0.05 – 0.21
 | style="vertical-align: top;  width: 56px" | 5,500[3]
 | style="vertical-align: top;  width: 57px" | 6,0
 | style="vertical-align: top;  width: 91px" | 1,99
+| style="vertical-align: top;  width: 106px" | 8<br/>($0.5 X 12 = wick
-| style="vertical-align: top;  width: 106px" | 8
-<br/>
-($0.5 X 12 = wick
 + $1 X 2 = glass)
-| style="vertical-align: top;  width: 76px" | 21,9
+| style="vertical-align: top;  width: 76px" | 21,9<br/>(0.03 ltr /hr @ $0.40 / ltr)
-<br/>
-(0.03 ltr /hr @ $0.40 / ltr)
 | style="vertical-align: top;  width: 76px" | 31,89
 | style="vertical-align: top;  width: 114px" | 31,89
 |-
 | style="vertical-align: top;  width: 91px" | Liquified Petroleum Gas (LPG)
 | style="vertical-align: top;  width: 69px" | 350 - 425
+| style="vertical-align: top;  width: 81px" | 330 – 1000(750)
-| style="vertical-align: top;  width: 81px" | 330 – 1000
-(750)
 | style="vertical-align: top;  width: 77px" | 0.94 – 2.35
 | style="vertical-align: top;  width: 56px" | 7,500[4]
 | style="vertical-align: top;  width: 57px" | 20,0
 | style="vertical-align: top;  width: 91px" | 4,867
+| style="vertical-align: top;  width: 106px" | 8($0.5 X 12 = mantle+ $1 X 2 = glass)
-| style="vertical-align: top;  width: 106px" | 8
+| style="vertical-align: top;  width: 76px" | 27,375(30 gm /hr @ $0.50 / kg)
-($0.5 X 12 = mantle
-+ $1 X 2 = glass)
-| style="vertical-align: top;  width: 76px" | 27,375
-(30 gm /hr @ $0.50 / kg)
 | style="vertical-align: top;  width: 76px" | 40,242
 | style="vertical-align: top;  width: 114px" | 40,242
 |-
 | style="vertical-align: top;  width: 91px" | Incande-scent
-<br/>
 | style="vertical-align: top;  width: 69px" | 100
 | style="vertical-align: top;  width: 81px" | 1200
 | style="vertical-align: top;  width: 77px" | 12
 | style="vertical-align: top;  width: 56px" | 1,200
 | style="vertical-align: top;  width: 57px" | 1,5
 | style="vertical-align: top;  width: 91px" | 2,28
 | style="vertical-align: top;  width: 106px" | 0
+| style="vertical-align: top;  width: 76px" | 12,78<br/>( $0,07/ kWh)
-| style="vertical-align: top;  width: 76px" | 12,78
-<br/>
-( $0,07/ kWh)
 | style="vertical-align: top;  width: 76px" | 15,06
+| style="vertical-align: top;  width: 114px" | 40,62<br/>( $0,21/ kWh)
-| style="vertical-align: top;  width: 114px" | 40,62
-<br/>
-( $0,21/ kWh)
 |-
 | style="vertical-align: top;  width: 91px" | Halogen
 | style="vertical-align: top;  width: 69px" | 25
 | style="vertical-align: top;  width: 81px" | 500
 | style="vertical-align: top;  width: 77px" | <font size="2">20</font>
 | style="vertical-align: top;  width: 56px" | 2,000
 | style="vertical-align: top;  width: 57px" | 6,5
 | style="vertical-align: top;  width: 91px" | 5,931
 | style="vertical-align: top;  width: 106px" | 0
+| style="vertical-align: top;  width: 76px" | 3,194<br/>( $0,07/ kWh)
-| style="vertical-align: top;  width: 76px" | 3,194
-<br/>
-( $0,07/ kWh)
 | style="vertical-align: top;  width: 76px" | 9,125
+| style="vertical-align: top;  width: 114px" | 15,513<br/>( $0,21/ kWh)
-| style="vertical-align: top;  width: 114px" | 15,513
-<br/>
-( $0,21/ kWh)
 |-
-| style="vertical-align: top;  width: 91px" | Floures-cent
+| style="vertical-align: top;  width: 91px" | Floures-cent(Ballast)26 mm tube diameter
-(Ballast)
-mm tube diameter
 | style="vertical-align: top;  width: 69px" | 18
 | style="vertical-align: top;  width: 81px" | 750
 | style="vertical-align: top;  width: 77px" | 45
 | style="vertical-align: top;  width: 56px" | 8,000
 | style="vertical-align: top;  width: 57px" | 17,0
 | style="vertical-align: top;  width: 91px" | 3,878
 | style="vertical-align: top;  width: 106px" | 0
+| style="vertical-align: top;  width: 76px" | 2,30<br/>( $0,07/ kWh)
-| style="vertical-align: top;  width: 76px" | 2,30
-<br/>
-( $0,07/ kWh)
 | style="vertical-align: top;  width: 76px" | 6,178
+| style="vertical-align: top;  width: 114px" | 10,778<br/>( $0,21/ kWh)
-| style="vertical-align: top;  width: 114px" | 10,778
-<br/>
-( $0,21/ kWh)
 |-
 | style="vertical-align: top;  width: 91px" | Compact Floures-cent
 | style="vertical-align: top;  width: 69px" | 5
 | style="vertical-align: top;  width: 81px" | 280
 | style="vertical-align: top;  width: 77px" | 56
 | style="vertical-align: top;  width: 56px" | 9,000
 | style="vertical-align: top;  width: 57px" | 8
 | style="vertical-align: top;  width: 91px" | 1,622
 | style="vertical-align: top;  width: 106px" | 0
+| style="vertical-align: top;  width: 76px" | 0,638<br/>( $0,07/ kWh)
-| style="vertical-align: top;  width: 76px" | 0,638
-<br/>
-( $0,07/ kWh)
 | style="vertical-align: top;  width: 76px" | 2,26
+| style="vertical-align: top;  width: 114px" | 3,536<br/>( $0,21/ kWh)
-| style="vertical-align: top;  width: 114px" | 3,536
-<br/>
-( $0,21/ kWh)
 |-
-| style="vertical-align: top;  width: 91px" | LED (5mm)
+| style="vertical-align: top;  width: 91px" | LED (5mm)(WhiteUltra bright)
-(White
-Ultra bright)
 | style="vertical-align: top;  width: 69px" | 1
 | style="vertical-align: top;  width: 81px" | 20
 | style="vertical-align: top;  width: 77px" | 20
-<br/>
 | style="vertical-align: top;  width: 56px" | 20,000[5]
+| style="vertical-align: top;  width: 57px" | 10 - 15(12.5)
-| style="vertical-align: top;  width: 57px" | 10 - 15
-(12.5)
 | style="vertical-align: top;  width: 91px" | 1,14
 | style="vertical-align: top;  width: 106px" | 0
+| style="vertical-align: top;  width: 76px" | 0,128<br/>( $0,07/ kWh)
-| style="vertical-align: top;  width: 76px" | 0,128
-<br/>
-( $0,07/ kWh)
 | style="vertical-align: top;  width: 76px" | 1,268
+| style="vertical-align: top;  width: 114px" | 1,524<br/>( $0,21/ kWh)
-| style="vertical-align: top;  width: 114px" | 1,524
-<br/>
-( $0,21/ kWh)
 |}
-<div><br/>----
+<div><br/>----<div id="ftn1">[1] Unit price includes all the lamp accessories/fittings, together with the lamp cost.</div><div id="ftn2">[2] Usually the unelectrified remote villages might be supplied with electricity generated from renewable energy sources and in this case, the cost/kWh might be as high as $0.21.</div><div id="ftn3">[3] The wick and the glass may have to be changed very frequently, though the other parts might stand for so many hours.</div><div id="ftn4">[4] The mantle and a few parts may have to be changed frequently.</div><div id="ftn5">[5] The life of an LED may depend on how efficiently the lamp is enclosed. The rapid advances in LED technology, the life is projected to increase dramatically. Similarly the life of a CFL depends on the no. of times it is switched on/off. The life of a halogen lamp depends on voltage fluctuations, etc.</div></div><br/><br/><br/>
-<div id="ftn1">[1] Unit price includes all the lamp accessories/fittings, together with the lamp cost.
-</div><div id="ftn2">[2] Usually the unelectrified remote villages might be supplied with electricity generated from renewable energy sources and in this case, the cost/kWh might be as high as $0.21.
-</div><div id="ftn3">[3] The wick and the glass may have to be changed very frequently, though the other parts might stand for so many hours.
-</div><div id="ftn4">[4] The mantle and a few parts may have to be changed frequently.
-</div><div id="ftn5">[5] The life of an LED may depend on how efficiently the lamp is enclosed. The rapid advances in LED technology, the life is projected to increase dramatically. Similarly the life of a CFL depends on the no. of times it is switched on/off. The life of a halogen lamp depends on voltage fluctuations, etc.
-</div></div><br/>
@@ Line 672: / Line 379: @@
 <br/></div>
 = <span><span><font size="3">SCOPE – A Layman’s Approach</font></span></span><font size="3"><span>for Appropriate Lighting Design</span></font><br/> =
-<div class="mw-collapsible mw-collapsed">Designing a lighting system appears complex and hence, it is better to have a systematic approach to arrive at a fair conclusion. Here, a simple practical approach to designing an optimum lighting system for a given setting is explained by five successive steps, namely, '''SCOPE'''. This approach might be adopted by any ordinary lighting designer aiming to provide adequate lighting for locations such as a house, health centre, school, streets, etc. The following paragraphs explain the approach in detail.
+<div class="mw-collapsible mw-collapsed">Designing a lighting system appears complex and hence, it is better to have a systematic approach to arrive at a fair conclusion. Here, a simple practical approach to designing an optimum lighting system for a given setting is explained by five successive steps, namely, '''SCOPE'''. This approach might be adopted by any ordinary lighting designer aiming to provide adequate lighting for locations such as a house, health centre, school, streets, etc. The following paragraphs explain the approach in detail.<br/><br/>
@@ Line 680: / Line 387: @@
 #<span></span>'''P'''review the costs involved
 #<span><span></span></span>'''E'''nd up deciding on an appropriate technology
+<br/>
+<br/>
 <br/>
@@ Line 730: / Line 441: @@
 |-
 | style="vertical-align: top;  width: 178px;  background-color: rgb(204, 204, 204)" | '''Type of Lamp'''
 | style="vertical-align: top;  width: 91px;  background-color: rgb(204, 204, 204)" | '''Luminous Efficacy (lm/W)'''
 |-
 | style="vertical-align: top;  width: 178px;  background-color: rgb(255, 255, 204)" | '''''Flame Based Lamps'''''
 | style="vertical-align: top;  width: 91px;  background-color: rgb(255, 255, 204)" | <br/>
 |-
 | style="vertical-align: top;  width: 178px" | Kerosene Lantern
 | style="vertical-align: top;  width: 91px" | 0.05 – 0.21
 |-
 | style="vertical-align: top;  width: 178px" | Kerosene Pressure Lamp
 | style="vertical-align: top;  width: 91px" | 0.39 – 1.60
 |-
 | style="vertical-align: top;  width: 178px" | Candle (Wax)
 | style="vertical-align: top;  width: 91px" | 0.02 – 0.22
 |-
 | style="vertical-align: top;  width: 178px" | Gas Lamp (LPG)
 | style="vertical-align: top;  width: 91px" | 0.94 – 2.35
 |-
 | style="vertical-align: top;  width: 178px" | Biogas Lamp
 | style="vertical-align: top;  width: 91px" | 0.48 – 0.94
 |-
 | style="vertical-align: top;  width: 178px" | <br/>
 | style="vertical-align: top;  width: 91px" | <br/>
 |-
 | style="vertical-align: top;  width: 178px;  background-color: rgb(255, 255, 204)" | '''''Electricity Based Lamps'''''
 | style="vertical-align: top;  width: 91px;  background-color: rgb(255, 255, 204)" | <br/>
 |-
 | style="vertical-align: top;  width: 178px" | Incandescent Lamp (100 W)
 | style="vertical-align: top;  width: 91px" | 12 - 15
 |-
 | style="vertical-align: top;  width: 178px" | Halogen Lamp (25 W)
 | style="vertical-align: top;  width: 91px" | 20 - 30
 |-
 | style="vertical-align: top;  width: 178px" | Fluorescent Tube (13 W)
 | style="vertical-align: top;  width: 91px" | 45 - 60
 |-
 | style="vertical-align: top;  width: 178px" | Fluorescent Lamp
 | style="vertical-align: top;  width: 91px" | 56 - 60
 |-
 | style="vertical-align: top;  width: 178px" | Compact Fluorescent Lamp
 | style="vertical-align: top;  width: 91px" | 50 - 90
 |-
 | style="vertical-align: top;  width: 178px" | Metal Halide
 | style="vertical-align: top;  width: 91px" | 80 - 120
 |-
 | style="vertical-align: top;  width: 178px" | High Pressure Sodium
 | style="vertical-align: top;  width: 91px" | 80 - 130
 |-
 | style="vertical-align: top;  width: 178px" | Low Pressure Sodium
 | style="vertical-align: top;  width: 91px" | 90 - 220
 |-
 | style="vertical-align: top;  width: 178px" | Light Emitting Diode Lamps
 | style="vertical-align: top;  width: 91px" | 25 - 150
 |}
 <br/>In the above case, the total light falling on the surface to be illuminated would now be: 1200/2 sq.m = 1200/4 = 300 lumens. But these 300 lumens can be made to be concentrated on an area of 1 sq.m or more area. Luminaires (light concentrators) concentrate the light emitted by a lamp in the required direction. If a luminaire is used the light is distributed uniformly in the spectrum specified by the manufacturer. If - for instance - the area of the room is about 10 sq.m, then - without a luminaire - the amount of light falling on the surface to be illuminated in the current example would be: 300/10 = 30 lux.
@@ Line 827: / Line 502: @@
 <br/>
-<div style="border-right: windowtext 1pt solid;  padding-right: 4pt;  border-top: windowtext 1pt solid;  padding-left: 4pt;  background: rgb(217,217,217);  padding-bottom: 1pt;  border-left: windowtext 1pt solid;  padding-top: 1pt;  border-bottom: windowtext 1pt solid">'''<span>Side Note: Calculation of Luminous Efficacy</span>'''
+<div style="border-right: windowtext 1pt solid;  padding-right: 4pt;  border-top: windowtext 1pt solid;  padding-left: 4pt;  background: rgb(217,217,217);  padding-bottom: 1pt;  border-left: windowtext 1pt solid;  padding-top: 1pt;  border-bottom: windowtext 1pt solid">'''<span>Side Note: Calculation of Luminous Efficacy</span>'''Luminous efficacy is usually provided in the lamp specifications provided by the manufacturer in the case of electricity based lighting devices. In the case of flame based lighting devices, it might be helpful to follow the typical values suggested by the research institutes, as cited in Tab.4. However, some details are given in the following paragraphs to calibrate the luminous efficacies of both the electricity based as well as the flame based lighting technologies:<br/>
-Luminous efficacy is usually provided in the lamp specifications provided by the manufacturer in the case of electricity based lighting devices. In the case of flame based lighting devices, it might be helpful to follow the typical values suggested by the research institutes, as cited in Tab.4. However, some details are given in the following paragraphs to calibrate the luminous efficacies of both the electricity based as well as the flame based lighting technologies:
-<br/>
 <u>Calculation of Luminous Efficacy of an electricity based lighting device</u>
@@ Line 857: / Line 528: @@
 If the luminous efficacies are not specified by the manufacturer, which is usually the case with flame based lighting options, it might be possible to use the following procedure to find out the same:
-<div>Amount of fuel (kerosene, gas) consumed by the lamp per hour = δ kg.
+<div>Amount of fuel (kerosene, gas) consumed by the lamp per hour = δ kg.Energy content of the fuel (kerosene) = 10 kWh per litre (or 12.5 kWh per kg)Energy content of the fuel (gas) = 12.5 kWh per kg.
-Energy content of the fuel (kerosene) = 10 kWh per litre (or 12.5 kWh per kg)
-Energy content of the fuel (gas) = 12.5 kWh per kg.
 [Also, it is possible to use the values from Table.3: (Energy content of a fuel in kWh = Energy content of the fuel in MJ / 3.6).]
@@ Line 895: / Line 562: @@
 <br/>
-</div>As lamps of a given wattage are available, it is possible to determine the exact amount of lighting that would reach the surface to be illuminated, with the lamp type considered using the procedure mentioned. If more illumination is required, then, it is necessary to consider the lamp types of higher power (or wattage) rating or consider a luminaire or a concentrator for the lamp. However, it is always possible to check the level of illumination on a given surface, simply by using a LUX meter.
+</div>As lamps of a given wattage are available, it is possible to determine the exact amount of lighting that would reach the surface to be illuminated, with the lamp type considered using the procedure mentioned. If more illumination is required, then, it is necessary to consider the lamp types of higher power (or wattage) rating or consider a luminaire or a concentrator for the lamp. However, it is always possible to check the level of illumination on a given surface, simply by using a LUX meter.<br/></div><br/></div>
-<br/>
-</div><br/></div>
 == <span><span><font size="3">Opt for an Ideal Lamp Type</font></span></span><br/> ==
-<div class="mw-collapsible mw-collapsed">Based on the procedures mentioned in the preceding paragraphs, it is easier to decide on a lamp type for a given situation. However, it should be noted that some lamps are best suited for certain applications.
+<div class="mw-collapsible mw-collapsed">Based on the procedures mentioned in the preceding paragraphs, it is easier to decide on a lamp type for a given situation. However, it should be noted that some lamps are best suited for certain applications.As a rule, fluorescents might be ideal for use in homes, work areas while Halogen lamps and LED based lamps might be ideal for focussed, task based lighting. Low pressure sodium lamps may be considered for parking areas. It is better to avoid the incandescent lamps as much as possible. It is also important to look at the availability of the lamp types in the market, for easy replacement.<br/>
-As a rule, fluorescents might be ideal for use in homes, work areas while Halogen lamps and LED based lamps might be ideal for focussed, task based lighting. Low pressure sodium lamps may be considered for parking areas. It is better to avoid the incandescent lamps as much as possible. It is also important to look at the availability of the lamp types in the market, for easy replacement.
-<br/>
 <u>Comparison of CFLs and LEDs</u>
@@ Line 925: / Line 584: @@
 <br/></div>
 == <span><span><font size="3">Preview the Costs Involved</font></span></span><br/> ==
-<div class="mw-collapsible mw-collapsed">Having considered various selection criteria for different technologies, it is important to have a preview of the costs involved in considering a specific option. It would be of advantage to calculate the total operating costs for one full year, for each lighting option, which would reflect the cost of the lamp, cost of energy, cost of labour and maintenance, as shown in Tab. 5 (see attached excel calculation sheet).
+<div class="mw-collapsible mw-collapsed">Having considered various selection criteria for different technologies, it is important to have a preview of the costs involved in considering a specific option. It would be of advantage to calculate the total operating costs for one full year, for each lighting option, which would reflect the cost of the lamp, cost of energy, cost of labour and maintenance, as shown in Tab. 5 (see attached excel calculation sheet).Tab. 5 serves as a guide with some typical lighting options, based on realistic values of the various specifications. The ultimate aim of Tab. 5 is to compute the annual operating costs of a lamp type.<br/>
-Tab. 5 serves as a guide with some typical lighting options, based on realistic values of the various specifications. The ultimate aim of Tab. 5 is to compute the annual operating costs of a lamp type.
-<br/>
 <p style="text-align: center">'''''Total Annu''al Operating Costs ='''<br/></p><p style="text-align: center">'''Lamp/Unit Costs / Year +'''<br/></p><p style="text-align: center">'''Maintenance Costs / Year +'''</p><p style="text-align: center">'''Electricity/Energy Costs/ Year'''</p>
@@ Line 1,011: / Line 666: @@
 <br/></div>
 == <span><span><font size="3">Summary: End Up Deciding on an Appropriate Lighting Method</font></span></span><br/> ==
-<div class="mw-collapsible mw-collapsed"><u>To summarise the steps explained in the previous sections:</u>
+<div class="mw-collapsible mw-collapsed"><u>To summarise the steps explained in the previous sections:</u><br/><br/>
@@ Line 1,032: / Line 687: @@
 *<span><span></span></span>Initial investment required for the lighting option.
 </div><br/>
 = Further Information<br/> =
 <div class="mw-collapsible mw-collapsed">
 *[[:File:Lighting technologies.pdf|PDF-Version]]
-*[[Light_Emitting_Diode_(LED)|Light Emitting Diode (LED)]]<br/>
+*[[Light Emitting Diode (LED)|Light Emitting Diode (LED)]]<br/>
 *[[Lighting|Lighting]]
 <br/></div>
 = References<br/> =
 <references />
 [[Category:Lighting]]

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Lighting Technologies

Revision as of 11:03, 19 January 2015

Contents

Overview

Luminous Intensity

Luminance

Luminous Flux

Illuminance

Repetitive Summary

Lighting Technologies

Flame-based Lighting

Electricity-based Lighting

Incandescent Lamps

Gas Discharge Lamps

Fluorescent Lamps

Compact Fluorescent Lamps (CFLs)

Low Pressure Sodium Lamps

Light Emitting Diodes (LEDs)

Synopsis of Efficiency and Costs of Various Lighting Technologies

Power of the Lighting Device

Luminous Performance or Efficacy

Life of a Device

Typical Unit Price

Annual Operating Costs

SCOPE – A Layman’s Approachfor Appropriate Lighting Design

Specify the Need

Consider the Lighting Options

Opt for an Ideal Lamp Type

Preview the Costs Involved

Summary: End Up Deciding on an Appropriate Lighting Method

Further Information

References