ImageVerifierCode 换一换
格式:PDF , 页数:29 ,大小:224.75KB ,
资源ID:1023121      下载积分:10000 积分
快捷下载
登录下载
邮箱/手机:
温馨提示:
如需开发票,请勿充值!快捷下载时,用户名和密码都是您填写的邮箱或者手机号,方便查询和重复下载(系统自动生成)。
如填写123,账号就是123,密码也是123。
特别说明:
请自助下载,系统不会自动发送文件的哦; 如果您已付费,想二次下载,请登录后访问:我的下载记录
支付方式: 支付宝扫码支付 微信扫码支付   
注意:如需开发票,请勿充值!
验证码:   换一换

加入VIP,免费下载
 

温馨提示:由于个人手机设置不同,如果发现不能下载,请复制以下地址【http://www.mydoc123.com/d-1023121.html】到电脑端继续下载(重复下载不扣费)。

已注册用户请登录:
账号:
密码:
验证码:   换一换
  忘记密码?
三方登录: 微信登录  

下载须知

1: 本站所有资源如无特殊说明,都需要本地电脑安装OFFICE2007和PDF阅读器。
2: 试题试卷类文档,如果标题没有明确说明有答案则都视为没有答案,请知晓。
3: 文件的所有权益归上传用户所有。
4. 未经权益所有人同意不得将文件中的内容挪作商业或盈利用途。
5. 本站仅提供交流平台,并不能对任何下载内容负责。
6. 下载文件中如有侵权或不适当内容,请与我们联系,我们立即纠正。
7. 本站不保证下载资源的准确性、安全性和完整性, 同时也不承担用户因使用这些下载资源对自己和他人造成任何形式的伤害或损失。

版权提示 | 免责声明

本文(SAE ARP 5572-2004 Control Measures for Laser Safety in the Navigable Airspace《通航空域中激光安全的控制措施》.pdf)为本站会员(diecharacter305)主动上传,麦多课文库仅提供信息存储空间,仅对用户上传内容的表现方式做保护处理,对上载内容本身不做任何修改或编辑。 若此文所含内容侵犯了您的版权或隐私,请立即通知麦多课文库(发送邮件至master@mydoc123.com或直接QQ联系客服),我们立即给予删除!

SAE ARP 5572-2004 Control Measures for Laser Safety in the Navigable Airspace《通航空域中激光安全的控制措施》.pdf

1、 AEROSPACE RECOMMENDED PRACTICE Control Measures for Laser Safety in the Navigable Airspace Issued 2004-01 ARP5572 INTRODUCTION On March 26, 1999, the FAA submitted a written request to SAE for assistance in developing standards and regulations concerning outdoor laser operations. In December 1999,

2、the SAE Aerospace Standard 4970 (AS4970) “Human Factors Considerations for Outdoor Laser Operations in the Navigable Airspace” was published by the SAE and forwarded to the FAA. AS4970 provides guidance on assessing the potential hazards of a particular laser beam. In August 2000, the ANSI Z-136.6-2

3、000 “American National Standard for Safe Use of Lasers Outdoors” was published. This Aerospace Recommended Practice (ARP) document provides guidance for control measures to be used optimally during operations of a laser system outdoors in the navigable airspace. It also recommends the control measur

4、e requirements for different outdoor laser systems. Reaffirmed 2010-02SAE 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 suitability for

5、 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. Copyright 2010

6、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 ORDER: Tel:

7、877-606-7323 (inside USA and Canada) Tel: 724-776-4970 (outside USA) Fax: 724-776-0790 Email: CustomerServicesae.org SAE WEB ADDRESS: http:/www.sae.org SAE values your input. To provide feedbackon this Technical Report, please visit http:/www.sae.org/technical/standards/ARP5572SAE ARP5572 - 2 - FORE

8、WORDThis document applies to control measures designed to mitigate a laser beams potential hazard to aircrews when projected from an outdoor laser system. Related Society of Automotive Engineers (SAE) documents are Aerospace Standard (AS4970) “Human Factors Considerations for Outdoor Laser Operation

9、s in the Navigable Airspace” and Aerospace Recommended Practice (ARP5535) “Observers for Laser Safety in the Navigable Airspace.”Additional control measures may be applicable and are discussed in ANSI Z-136.6-2000, “American National Standard for Safe Use of Lasers Outdoors,” which is the most recen

10、t and authoritative reference regarding outdoor laser operations and control. The purpose of this document is to provide guidance to all laser operators, including industry and government, and to the Federal Aviation Administration (FAA) on the optimal use of control measures during propagation of a

11、 laser beam in the navigable airspace. It also discusses control measures for systems that generate these beams. The SAE G-10T Committee has convened during the past 7 years with representation from at least 17 different entities, public and private, to identify the issues, technologies, and operati

12、onal capabilities of outdoor laser use in navigable airspace. SAE ARP5572 - 3 - TABLE OF CONTENTS 1. SCOPE 4 1.1 Purpose4 1.2 Field of Application.4 2. REFERENCES.4 2.1 Applicable Documents .4 2.1.1 SAE Publications4 2.1.2 ANSI Publications 5 2.1.3 U.S. Government Publications .5 2.2 Other Applicabl

13、e References .5 2.3 Definitions 5 3. LASER CONTROL MEASURES9 3.1 Safety Observers .93.2 Radar .10 3.2.1 Boresight Radar .11 3.2.2 Scanning Radar (Sweeping for laser safety standards, 0.18 to 0.38 m.VISIBLE RADIATION: See LIGHT. WAVELENGTH: The distance between two successive points on a periodic wav

14、e of optical radiation. It is commonly used to provide a numeric description of the color of visible laser radiation. SAE ARP5572 - 9 - 3. LASER CONTROL MEASURES: The following control measures are effective only if the laser system is appropriately installed and operated in accordance with federal,

15、 state, and local regulations, and industry standards. Issues of concern include stability of the laser and platform, physical access to the laser, pointing accuracy of the laser beam, protective housings, and unwanted wavelengths of laser energy. These issues need to be addressed. Detailed safety i

16、nformation is available in ANSI Z136.1-2000 and Z136.6-2000. 3.1 Safety Observers: The safety observer is one of the more proven methods of ensuring that aircraft are not illuminated in-flight by a laser beam. Distance, atmospheric, and environmental parameters may reduce the effectiveness of safety

17、 observers. Additionally, the wavelength (visible versus non-visible) of the laser beam may further reduce the ability of the safety observer to identify the affected airspace. Safety observers may be used in conjunction with other control measures for high-powered laser systems. Safety observers ha

18、ve been demonstrated to be reliable in detecting aircraft at night within short distances (i.e., within about 3 miles) in populated areas. They may be reliable in detecting aircraft farther in semi-populated areas and at much greater distances in remote locations, where city lights are not encounter

19、ed. The Laser Safety Officer (LSO) should not rely solely on safety observers if aircraft can be exposed to hazardous levels of laser energy beyond the observers effective visual range. Safety observers have limited visible range, require training, need frequent breaks, and may be affected by certai

20、n environmental conditions. However, safety observers may have a wider field of view when scanning the airspace, may be readily available, and may be more economical for short-term laser operations. Guidance to FAA personnel reviewing laser demonstration requests and to the laser proponent concernin

21、g the optimal use of safety observers during operation of a laser system is discussed in SAE ARP5535 (Observers for Laser Safety in the Navigable Airspace). That document reviews issues such as vision standards, training, optical aids for the observer, and evaluation of observer effectiveness. SAE A

22、RP5572 - 10 - 3.2 Radar: Radar sends out a radio frequency (RF) signal and displays the signal return reflected from an object. The distance to the object is calculated from the amount of time the signal takes to travel to-and-from the object. Radar is restricted to line-of-sight. Aircraft maneuvers

23、, such as steep turns, rapid climbs or descents, can degrade the radar reflection. Radar is subject to limitations including atmospheric conditions, missed targets, false returns, ground clutter, RF interference, etc. Here is a summary of the general pros and cons of all radar systems: Pros:a. Provi

24、des near real-time to real-time, accurate, long-range information of aircraft positions in the area b. May allow the laser operator to propagate the laser beam at a lower elevation angle c. Especially valuable in the daytime or in inclement weather d. Extended airspace coverage beyond safety observe

25、r capabilities e. Tracking of multiple aircraft simultaneously f. May be used as an automated laser control measure Cons:a. Limited elevation coverage b. Potentially expensive c. May produce hazardous RF emissions d. Susceptible to false or missed radar data e. May require Federal Communications Com

26、mission (FCC) concurrence SAE ARP5572 - 11 - 3.2.1 Boresight Radar: A boresight radar system is typically comprised of control electronics, a transmitter/receiver (transceiver), a radar antenna, and a gimbaled mount. The control electronics performs the following tasks: a. Accepts pointing informati

27、on from the laser system b. Commands the gimbal to point in the direction of the laser beam propagation c. Commands the radar transceiver d. Processes the information gathered by the transceiver e. Indicates that an aircraft is detected f. Abates the laser g. Insures the overall control system is op

28、erational The transceiver develops and transmits the radio frequency (RF) energy and receives the reflected RF signal. The gimbaled mount supports the transceiver and points the transceiver radar antenna. The radar antenna can either be mounted directly to the laser gimbal or can be mounted to a sep

29、arate gimbal. The design of the boresight radar must cover the airspace of concern. Command information is accepted from the laser system by the control electronics. In turn, the control electronics points the transceiver antenna and tracks along the path of the transmitted laser energy. The RF beam

30、 is transmitted by the transceiver antenna and surrounds the laser beam.The envelope of RF energy is several orders of magnitude larger than the envelope of laser energy. Since the radar continually monitors the airspace surrounding the laser beam, reflected RF energy is immediately detected when a

31、plane flies into the path of the radar beam. The control electronics processes this reflected information and develops the aircraft detect signal. This aircraft detect signal is then used to trigger a laser beam abatement system and provides an indicator to the laser operator. See Figure 1. SAE ARP5

32、572 - 12 - FIGURE 1 Boresight Radar System Showing Overlap of RF Energy with Transmitted Laser Energy 3.2.1 (Continued): Boresight radar systems are typically used by scientific, research, or military laser operations that transmit laser energy through the navigable airspace. Satellite laser ranging

33、 systems, LIDAR systems, and guide star optical telescopes have used this system either by itself, or in combination with other aircraft detection systems, such as safety observers or cameras. Boresight radar systems are commercially available. As with any control measure, the capability of a boresi

34、ght system should be evaluated based on the specific proposed operation. Since the radar is pointing along the transmitted laser beam and constantly monitoring the airspace, it is extremely reliable for detecting aircraft. In addition, the time from detection of the aircraft to the development of th

35、e aircraft detect signal is usually in milliseconds. These laser abatement systems may be situated in remote locations or placed near densely populated areas. The boresight radar system is effective even when other control systems are hampered by poor visibility. The boresight radar has a wide range

36、 of coverage (from a few hundred feet to tens of miles). Its very quick response time lends itself well to areas of high-volume air traffic. SAE ARP5572 - 13 - 3.2.1 (Continued): The boresight radar system would not be used when there is a potential that transmitted RF energy may interfere with othe

37、r established operations, such as communication transmissions, deep space monitoring systems, and radio telescopes. Also, the boresight radar system should not be used if ground based objects interfere with the capability of the system. Therefore, not all boresight radar systems are well suited for

38、laser systems that transmit laser energy close to the ground. Local and federal laws and regulations may limit the use of RF energy generating devices, such as radar systems. A boresight radar system can be totally automated. The control electronics of an automated boresight radar system are connect

39、ed to the laser beam abatement system to allow automatic abatement upon aircraft detection. Otherwise, an operator would need to abate the laser manually. Once the aircraft has left the air space monitored by the boresight radar, the system can either be reset automatically or manually to once again

40、 allow transmission of the laser energy through navigable airspace. Here is a summary of the pros and cons of boresight radar systems: Pros:a. Provides real-time information on position of aircraft in the area b. Lowest transmitted RF power of any radar system c. Least expensive radar system d. Wide

41、ly used automated system Cons:a. Laser beams are limited to the restricted field of view of the boresight radar system Bound by the inherent limitations of any radar system Boresight radars vary in efficacy SAE ARP5572 - 14 - 3.2.2 Scanning Radar (Sweeping & Panning): Scanning radars encompass a vas

42、t array of equipment ranging from inexpensive, portable, analog radar, such as one used on a small boat (see Figure 2), to a permanent installation of a multi-million dollar digital radar system (see Figure 3). Permanent radar site installations require costly and timely environmental studies as wel

43、l as ongoing maintenance and operation costs. FIGURE 2 Analog Marine Radar FIGURE 3 FAA Digital Radar Site A scanning radar system rotates or oscillates about an axis. The time to perform a complete rotation varies among different radar systems. Sixty-mile range radar system used by some air traffic

44、 control facilities rotate about every 4 seconds. The rotation time prevents display of a smooth, continuous movement of the aircraft. The direction and speed of the aircraft and the radar rotation time must be taken into account to predict the aircrafts projected position. For example, a jet aircra

45、ft flying at 250 knots could be approximately 0.3 NM from its last known position before the radar completes its rotation and updates the aircraft location. SAE ARP5572 - 15 - 3.2.2 (Continued): The distance and coverage angles of scanning radar systems differ widely. Sweeping radar systems scan 360

46、 about a vertical axis and have a conical volume of airspace directly above the radar antenna that is excluded from radar coverage sometimes called a blind spot. Panning radar systems scan only a portion of the airspace. Used on a limited basis in military applications, a proof of concept has not be

47、en established for the FAA in non-military laser applications. Although possibly enhancing situational awareness, scanning radar may be of limited value to the laser operator. Here is a summary of the pros and cons of scanning radar systems: Pros:a. Up to 360 coverage Cons:a. More expensive than a b

48、oresight radar system b. Higher transmitted RF power than boresight radar system c. Near real-time radar data may be substantially delayed d. Bound by the inherent limitations of all radar systems 3.2.3 Phased Array Radar: Phased array radar systems utilize a specific geometrical arrangement of stat

49、ionary antennas and software to emulate the abilities of sweeping and boresight radars. A phased array radar has no refresh delay or high elevation angle exclusion zones. Additionally, these radar systems are very expensive and have high maintenance costs. The phased array radar permits complete flexibility in its use.Search and tracking functions can be adjusted to optimum use based on local conditions. The radar beam width, azimuth, and elevation can be adjusted to search certain areas more rapidly than others. Even the power transmitted by each element

copyright@ 2008-2019 麦多课文库(www.mydoc123.com)网站版权所有
备案/许可证编号:苏ICP备17064731号-1