ImageVerifierCode 换一换
格式:PDF , 页数:3 ,大小:90.94KB ,
资源ID:792145      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-792145.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(ITU-R P 1060-1994 Propagation Factors Affecting Frequency Sharing in HF Terrestrial Syatems《高频地面系统中影响频率共享的传播因素》.pdf)为本站会员(registerpick115)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!

ITU-R P 1060-1994 Propagation Factors Affecting Frequency Sharing in HF Terrestrial Syatems《高频地面系统中影响频率共享的传播因素》.pdf

1、 Rec. ITU-R P.1060 1 RECOMMENDATION ITU-R P.1060*PROPAGATION FACTORS AFFECTING FREQUENCY SHARING IN HF TERRESTRIAL SYSTEMS (Question ITU-R 219/3) (1994) Rec. ITU-R P.1060 The ITU Radiocommunication Assembly, considering a) that frequency sharing at HF is difficult in practice because of the nature o

2、f the ionosphere and ionospheric propagation; b) that models of both short- and long-term variability in ionospheric propagation may facilitate improved frequency sharing; c) that modern frequency agile communications systems provide new techniques for increasing frequency sharing, recommends 1. tha

3、t the propagation factors indicated in Annex 1 should be taken into account when designing, planning and operating radiocommunication services or systems in the HF band. ANNEX 1 1. Introduction Limitations on the sharing of radio frequencies in the HF spectrum are dependent on the propagation charac

4、teristics of ionospheric radiowaves. Frequency sharing at HF has been found to be extremely difficult because radiowaves propagating via the ionosphere do not attenuate quickly. Any attempt at frequency sharing must consider the facts that at HF, radiowaves normally propagate in all directions; radi

5、owaves are refracted and reflected by the ionosphere and the ground and will continue until dissipated. In the highly congested HF band the occupancy of individual channels and possible co-frequency allocation vary with the type of service, frequency, time-of-day, season, angle of arrival, type of r

6、eceiving antenna, bandwidth, service threshold, geographic location and solar activity. Recommendation ITU-R M.831 addresses the technical factors to be taken into account when preparing studies relating to sharing between fixed and other services at frequencies below 30 MHz. Of the factors highligh

7、ted, that of circuit predictability concerns the propagation of ionospheric waves. 2. Signal strength The possibilities of co-frequency assignment at HF hinge on the signal intensities of wanted and unwanted signals at the receiving site. Because the signal intensity is dependent on the propagation

8、path, reduction of the unwanted signal requires separation by geographic distance (assuming transmissions cannot be interleaved in time) between the receiver and the unwanted transmitter. Transmitted powers should be kept to the minimum necessary to provide a satisfactory service. _ *Radiocommunicat

9、ion Study Group 3 made editorial amendments to this Recommendation in 2000 in accordance with Resolution ITU-R 44. 2 Rec. ITU-R P.1060 Propagation via the ionosphere is governed by the frequency of the signal relative to the plasma density of the ionosphere. Variations in the ionization density of t

10、he ionosphere will affect the propagation characteristics such as signal intensity (through transmission losses), polarization and Doppler shift. Ionospheric density and structure vary with time of day, season, solar cycle and location, and must be taken into account when determining transmission ch

11、aracteristics so as to maintain the minimum required signal strength at the receiver. 3. Signal attenuation To optimize frequency sharing, radio services need to restrict their transmissions to their zone of interest. Because HF signals continue to propagate past the receiver site, it is important t

12、o limit the signal intensity at the receiver to the minimum required by optimizing characteristics that cause the signal to decay swiftly beyond the receiving location, such as frequency, and antenna vertical radiation angle. The signal attenuation loss over a propagation path is made up of free-spa

13、ce loss, ionospheric loss, ground reflection loss and polarization loss. From this one can expect the signal to attenuate fastest when: the frequency is close to the LUF; the elevation angle is higher than optimum for the path (many small hops); the ray path is long; the circuit is over lossy ground

14、. To cause the signal to decay rapidly beyond the receiving site, it is desirable to operate at a frequency close to the lower limit of the available frequency range for the particular circuit. However this can be in conflict with signal quality which generally increases as the frequency approaches

15、the MUF. Optimizing the signal requires a clear definition of the necessary service margins at the receiver and a knowledge of the behaviour of the signal under various ionospheric conditions. 4. Skip zone At a distance close to the transmitter but beyond the limit of ground waves, there can be a zo

16、ne where sky waves from the transmitter cannot reach because they exceed the MUF and pass through the ionosphere. Theoretically this provides a zone in which frequency sharing can operate. However, in practice measurements have indicated that signals can penetrate into the skip zone by sidescatter.

17、5. The use of propagation models Radio propagation prediction models such as that of Recommendation ITU-R P.533 can provide guidance on the expected characteristics of circuits. This information can be used to indicate where there may be possibilities for the sharing of frequencies. These models are

18、 based on average behaviour and should not be expected to give results beyond their statistical capabilities. For example they do not predict well the behaviour of ionospheric propagation in the equatorial region where the anomaly can cause transient variations from the normal modes of propagation a

19、nd high signal intensities can be transmitted over long distances. Again, sporadic-E propagation can cause interference which will not be predicted by the models. In the high latitude regions there are irregularities and transient phenomena which cannot be accounted for by the models. Rec. ITU-R P.1

20、060 3 6. Variations in propagation While models can provide a statistical guide to circuits that may share frequencies, the effect of real variations in the ionospheric propagation needs to be considered. Variations in propagation and the reality of signal strength fading should be accounted for by

21、making allowance for the expected variation. Report ITU-R P.266 provides the background information on the nature of these variations while Recommendations ITU-R F.339 and ITU-R BS.411 give values for fading allowances for fixed and broadcasting service applications. Unwanted signals can propagate b

22、eyond their intended reception area to an unpredictable extent when sporadic-E layers are present (Recommendation ITU-R P.534 provides occurrence statistics for sporadic E), when tilts are prominent near the ionospheric reflection point or when irregularities in the ionospheric density give rise to

23、sidescattered signals. Most of these phenomena occur at certain times of the day, season or solar cycle and there is a case for dynamic assignment of frequencies where the use of shared frequencies would be withdrawn during the periods of abnormal propagation. 7. Frequency agile systems Dynamic freq

24、uency sharing or real-time frequency management is a useful tool for providing communication circuits that are not otherwise possible because of interference constraints. Dynamic sharing implies operation on a secondary basis where there is no possibility of a claim for interference-free communicati

25、on. This type of sharing is possible with frequency-agile transmitting and receiving equipment made feasible by modern technology. Dynamic frequency sharing is particularly effective when one service operates with high power on known or published frequencies, such as the broadcasting service and the

26、 dynamic service operates with low power involving two-way communications such as in the fixed, mobile and amateur services. Real-time channel evaluation (RTCE) systems, which test the quality of a specific circuit over a set of channel frequencies in real-time, provide the means of matching current

27、 propagation conditions over the circuit with the frequencies available. Radio systems incorporating RTCE are becoming available and use of such techniques is likely to increase. RTCE can provide a means of automatically selecting the best frequency and simultaneously indicating stand-by channels. O

28、ften the best frequency is chosen to be that which maximizes the ratio of signal-to-background-noise-plus-interference. Consideration should be given to the selection of working frequencies which are sub-optimum but which are less likely to interfere with other users of the spectrum. Some RTCE equip

29、ped communication links may also have the capability to adapt transmitter power levels so that an acceptable grade of service is achieved with the minimum radiated power. Techniques such as this, which can maximize the opportunity for frequency sharing, should be encouraged. When using RTCE systems

30、it should be recognized that the optimization of one circuit may give rise to interference on another. Intelligent control systems which can respond rapidly to null out interfering signals by means of adaptive antennas give the promise of increasing the chances of frequency sharing and are recommend

31、ed in the situation of a few strong interferers. 8. Summary The feasibility of frequency sharing in a particular scenario depends on compatibility, that is, meeting the specified protection ratio for the required percentage of time (recommended protection ratios for use in sound broadcasting and for

32、 the fixed services appear respectively in Recommendations ITU-R BS.560 and ITU-R F.240). Transmitted power and propagation loss are paramount factors in determining whether or not there is compatibility between emissions. For this reason there are particular advantages in having like services with

33、comparable radiated powers sharing the same bands. Propagation loss depends to a first order on distance so that sharing is more likely to be possible where the geographical separations between co-channel and adjacent channel emissions are greatest. With the crowded nature of the spectrum, sharing must be adopted and each case of potential harmful interference needs to be assessed separately.

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