SAE ARP 4168A-2004 Night Vision Goggle (NVG) Compatible Light Sources《夜视镜(NVG)兼容光源》.pdf

1、 AEROSPACE RECOMMENDED PRACTICE Night Vision Goggle (NVG) Compatible Light Sources SAE Technical Standards Board Rules provide that: “This report is published by SAE to advance the state of technical and engineering sciences. The use of this report is entirely voluntary, and its applicability and su

2、itability for any particular use, including any patent infringement arising therefrom, is the sole responsibility of the user.” SAE reviews each technical report at least every five years at which time it may be reaffirmed, revised, or cancelled. SAE invites your written comments and suggestions. Co

3、pyright 2004 SAE International All rights reserved. No part of this publication may be reproduced, stored in a retrieval system or transmitted, in any form or by any means, electronic, mechanical, photocopying, recording, or otherwise, without the prior written permission of SAE. TO PLACE A DOCUMENT

4、 ORDER: Tel: 877-606-7323 (inside USA and Canada) Tel: 724-776-4970 (outside USA) Fax: 724-776-0790 Email: custsvcsae.org SAE WEB ADDRESS: http:/www.sae.org Issued 1988-09 Revised 2004-01 Superseding ARP4168 ARP4168 REV.A FOREWORD Changes in this revision are format/editorial only. 1. SCOPE: 1.1 Thi

5、s ARP covers three common lamp light sources, incandescent, electroluminescent and light emitting diode that, when NVG filtered, can be used to illuminate NVG compatible aerospace crew stations. It is recognized that many other different light sources can also be used for this purpose. 1.2 This ARP

6、sets forth recommendations for the design of NVG compatible lighting, utilizing these light sources, that will meet the requirements of MIL-L-85762A Lighting, Aircraft, Interior, Night Vision Imaging System (NVIS) Compatible. 1.3 Although this ARP concentrates on lamp light sources for illumination,

7、 the information contained within this ARP may be directly applied to incandescent, electroluminescent and light emitting diode information display devices. 2. PURPOSE: 2.1 This SAE Aerospace Recommended Practice recommends certain basic considerations which the design engineer should observe when d

8、esigning NVG compatible lighting. Copyright SAE International Provided by IHS under license with SAENot for ResaleNo reproduction or networking permitted without license from IHS-,-,-SAE ARP4168 Revision A - 2 - 2.2 Definition: Night vision goggle compatible lighting is the condition in which the sp

9、ectral wavelengths, luminance level and uniformity of the cockpit lighting do not interfere with the operation of night vision goggles. NVG compatible lighting permits a crew member to observe outside scenes through night vision goggles while maintaining the ability to recognize master caution/warni

10、ng indicators inside the cockpit. Also, with NVG compatible lighting, all necessary information in the crew station is easily seen by a crew member with unaided eyes. 3. RECOMMENDATIONS: When designing for NVG compatible lighting, the designer must consider that all light sources require varying deg

11、rees of optical filtration to restrict emissions above 600 nm. The degree of restriction is dependent upon the color and NVIS Radiance (NR) as defined in MIL-L-85762A. This is necessary since night vision goggles are most sensitive to long wavelength emission. Without the proper filtration, the ligh

12、t source will degrade or shut down the operation of a night vision goggle. NVG filtered lighting must be dimmable to levels as low as 0.1 fL in order to meet NVG compatibility requirements. If a combination of NVG light sources are utilized in a single piece of equipment, it is desirable to have one

13、 control that will dim all the light sources simultaneously. When using a common dimming circuit, considerations should be given to the luminance tracking characteristics of the different light sources. The possible requirement for sunlight readability should also be considered when selecting the li

14、ght sources. 3.1 Incandescent Lamps: 3.1.1 Lamp Types: Some typical military specifications for incandescent lamps that are used in aerospace vehicle panels are listed in Table 1. The size and type of lamp should be selected to meet the specific requirements of the application. Military specified la

15、mps should be used whenever possible. However, in some instances it may be necessary to deviate from MIL specifications in order to meet special lighting and packaging requirements. Copyright SAE International Provided by IHS under license with SAENot for ResaleNo reproduction or networking permitte

16、d without license from IHS-,-,-SAE ARP4168 Revision A - 3 - TABLE 1 - Military Specifications for Incandescent Lamps MILITARY SPECIFICATION LAMP TYPE MS 90452 MS 24367 MS 90451 MS 24515 MS 3338 MS 25237 MS 25238 MS 15570 MS 25478 MS 25235 T-3/4, 5.0 Volt, Wire Terminals T-1, 5.0 Volt, Wire Terminals

17、 T-1, Short Length, 5.0 Volt, Wire Terminals T-1, 5.0 Volt, Based T-1, 28.0 Volt, Based T-1 3/4, 2.5 to 28.0 Volt, Based G-5, 28.0 Volts, Based G-6, 6.0 to 28.0 Volts, Based S-8, 6.0 to 28 Volts, Based S-11, 28.0 Volts, Based 3.1.2 Design Considerations: 3.1.2.1 Light Output: Incandescent lamps emit

18、 light by the resistance heating of a tungsten wire filament to incandescent temperatures above 1200K inside a vacuum or inert gas filled envelope. They are broad band illuminators that follow the typical black body radiation curves. Most subminiature lamps operate in the 1600 - 2400K filament color

19、 temperature range as shown in Fig. 1. Less than 8% of the energy emitted is within the visible spectrum from blue to red. The remaining energy is in the infrared where NVIS systems are most sensitive. When properly filtered, incandescent light sources will meet the NR and color requirements of MIL-

20、L-85762A. Incandescent lamps range from 0.001 mean spherical candelas (MSCD) to 1.0+ MSCD in the subminiature sizes. An NVG filter will reduce the available light and should shift the observed spectral distribution from white to the desired NVG color. Thus, incandescent lamps must be selected to pro

21、vide sufficient illumination through the NVG filter. 3.1.2.2 Size of Lamp: The physical size of the lamp must fit within the available space. Miniature and subminiature incandescent lamps are available in a wide range of sizes from less than 0.030 inches to more than 1.5 inches in diameter. The sele

22、cted lamp should be configured with the proper base design to meet maintenance requirements. 3.1.2.3 Power Dissipation: The designer needs to select an incandescent lamp that is compatible with available power. Either AC or DC power may be used. Typical incandescent lamps in aerospace applications u

23、se 5.0 or 28 V, 0.02 - 1.0 A. 3.1.2.4 Thermal Considerations: Ambient temperatures of -55C to +100C will normally not affect the life or operation of standard incandescent lamps. It is recommended that the designer allow for sufficient heat dissipation, where applicable, in order to maintain the pro

24、per lamp surface temperature. Copyright SAE International Provided by IHS under license with SAENot for ResaleNo reproduction or networking permitted without license from IHS-,-,-SAE ARP4168 Revision A - 4 - 3.1.2.5 Dimming: Incandescent lamps are voltage operated devices. The light output is dimmed

25、 by reducing the applied voltage. The dimmed light output varies exponentially, as determined by Equation 1. 5.3VoltageRatedVoltageDimmed)MSCD(OutputLightOutputLightRated)MSCD(OutputLightLightDimmed= (1) As an incandescent lamp is dimmed, a spectral shift occurs towards longer wavelengths. This spec

26、tral shift causes a color shift towards red, a change in the spectral relationship with respect to the filters transmission characteristic and will affect the NR value. These effects must be factored into the overall lighting system design to assure that the spectrum (color) of the NVG filtered inca

27、ndescent lamp is within the desired NVIS color range at the dimmed brightness level specified in MIL-L-85762A. 3.2 Electroluminescent (EL) Lamps: 3.2.1 Lamp Types: AC thick-film electroluminescent lamps use phosphors to convert electrical energy into light energy. Only a small amount of infrared ene

28、rgy is emitted by an EL lamp. AC thick-film EL lamps are available in both blue-green and yellow, and when NVG filtered, may be used for NVG compatible lighting. When properly NVG filtered, EL lamps meet the NVG compatibility requirements of MIL-L-85762A. 3.2.2 Design Considerations: 3.2.2.1 Light O

29、utput: The spectral distribution of a blue-green AC EL lamp is presented in Fig. 2. The light output for a blue-green EL is typically 20 fL at 115 V AC, 400 Hz. The light output will be reduced by an NVG filter and the designer needs to take this into account. The light output of an EL lamp degrades

30、 exponentially with operating life. 3.2.2.2 Size of Lamps: EL lamps are flat, thin (0.015 in - 0.040 in) capacitive devices. EL lamps are available in any size from 0.1 in x 0.1 in - 12 in x 12 in, or larger, if necessary. Each lamp design may be custom configured in shape, with cutouts and other fe

31、atures to meet the needs of a specific application. 3.2.2.3 Power Dissipation: AC EL lamps are typically driven from 0 - 115 V AC, 400 Hz. The drive current required is typically 2 mA/in2of illuminated area at full rated voltage. With a 70 deg or 80 deg leading phase angle, power dissipated is typic

32、ally 40 - 80 mW/in2. The power dissipated in an EL lamp is equal to the voltage applied to the lamp x current x cosine of the phase angle, Equation 2. = CosIV)LampEL(P (2) Copyright SAE International Provided by IHS under license with SAENot for ResaleNo reproduction or networking permitted without

33、license from IHS-,-,-SAE ARP4168 Revision A - 5 - 3.2.2.4 Thermal Considerations: Because no heating of the phosphor is required for luminescence, an extremely low amount of heat is generated by an EL lamp. Long term, extended use at elevated temperatures (greater than 55C) is not recommended as ope

34、rating life is reduced. During operation at elevated temperatures, light output degradation is accelerated. Light output degradation does return to normal when the ambient temperature falls below 55C. 3.2.2.5 Dimming: EL lamps should be considered to be voltage operated devices. Dimming is accomplis

35、hed by reducing the applied voltage. Light output varies as shown in Fig. 3. There is no shift in spectral distribution with voltage dimming. Since there is a small spectral shift with frequency variation, large frequency variations should be avoided. 3.3 Light Emitting Diode (LED) Lamps: 3.3.1 Lamp

36、 Types: LED lamps are solid state devices in two basic configurations, individual lamps and light bars, and are available in military and plastic packages. With the correct NVG filters, LED lamps meet the NVG compatibility requirements of MIL-L-85762A. Typical LED colors are given in Table 2. TABLE

37、2 - Typical Colors of LED Devices Used With Night Vision Goggles LED COLOR DOMINANT WAVELENGTH (d) SATURATED COLOR Green Yellow 565 - 572 nm 582 - 592 nm yellow-green yellowish-orange 3.3.2 Design Considerations: 3.3.2.1 Light Output: LED devices are narrow band emitters that generate light by elect

38、ron-hole recombination across a semiconductor p-n junction. The radiated spectra for green and yellow LEDs are shown in Fig. 4. The light output of an LED lamp is specified as luminous intensity, flux per unit solid angle. The unit used is the candela (cd), lumens per steradian. The luminous intensi

39、ty for an LED lamp is typically on the order of microcandelas (cd) to millicandelas (mcd). Some LED devices have sufficient light output to be readable in daylight conditions, when filtered by the correct night vision goggle/daylight viewing (NVG/DV) filter. 3.3.2.2 Size of Lamp: Military grade LED

40、lamps use a T0-46 hermetic package. NVG military grade LED panel mount lamps are available with an NVG filter incorporated as an integral part of the panel mount sleeve. Plastic encapsulated LED lamps are available in T-1 3/4, T-1 and subminiature packages. Plastic light bars, typically used as annu

41、nciators, come in illuminated area sizes ranging from 0.10 in x 0.20 in to 0.4 in x 0.80 in. Copyright SAE International Provided by IHS under license with SAENot for ResaleNo reproduction or networking permitted without license from IHS-,-,-SAE ARP4168 Revision A - 6 - 3.3.2.3 Power Dissipation: LE

42、D lamps are current operated devices, and a current limiting resistor is required (see Fig. 5). The value of the current limiting resistor may be determined from Equation 3. Maximum DC drive currents range between 30 and 50 mA, with a typical forward voltage drop of 2.2 V. LED lamps may also be puls

43、e driven (strobed) with typical power dissipations in the range of 0.090 to 0.140 mW. ()LED(I)LED(VVV)Limiter(RFFSATCC+= (3) 3.3.2.4 Thermal Considerations: The light output and operating life of LED lamps are functions of the LED junction temperature. As the LED junction temperature is increased du

44、e to a high thermal resistance, the light output and operating life decrease accordingly. LED light output decreases approximately 1.5% per 1C increase in junction temperature. Also, mean time between failure (MTBF) decreases by a factor of 2 for each 20C increase in junction temperature. Therefore,

45、 it is desirable to design the LED mounting configuration with as low a thermal resistance to ambient as possible to keep the LED junction temperature as low as possible. This will help to assure sufficient light output and expected operating life performance. The ambient operating temperature range

46、 is depending upon the type of LED lamp (see Table 3). Any LED lamp may be operated at its specified operating temperature limit without undue degradation. TABLE 3 - Typical Operating Temperature Ranges for Green LED Devices TYPE OF LED LAMP OPERATING TEMPERATURE RANGE Military Grade Lamps Plastic L

47、amps Plastic Light Bars -55C to +100C -20C to +100C -20C to +85C 3.3.2.5 Dimming: Dimming of a DC driven LED lamp is accomplished by reducing the forward drive current. Dimming of a strobed LED lamp at a fixed refresh rate is accomplished by pulse width modulation (PWM) of the on time pulse. When PW

48、M is used, the light output of an LED varies directly with the proportioned on time pulse; that is, 50% on time appears as 50% brightness, 10% on time appears as 10% brightness. 4. RELIABILITY TESTING: 4.1 Incandescent Lamps: Incandescent lamps are generally tested per MIL-STD-202 and MIL-STD-810. L

49、ower voltage lamps are typically selected for their resistance to mechanical shock and vibration. Copyright SAE International Provided by IHS under license with SAENot for ResaleNo reproduction or networking permitted without license from IHS-,-,-SAE ARP4168 Revision A - 7 - 4.2 Electroluminescent Lamps: Electroluminescent lamps are typically tested to the requirements specified in a source control drawing. The c