基于小波变换的单脉冲雷达目标RCS测量方法研究

随着现代信号处理技术的发展,对非平稳信号分析和处理的小波分析技术已成功应用于雷达目标特性分析领域,大功率单脉冲雷达作为我国航天测控网的主干设备,具有一定的目标特性识别能力。本文主要针对脉冲雷达RCS测量原理,讨论了基于小波变换的单脉冲雷达空间目标RCS测量方法,提出应发挥窄带低分辨率雷达在未来空间目标识别中的作用。     

《飞行器测控技术》1985年总目录

浦控总体远站跟踪转换方程的推导速度状态参数的最优观测几何试验靶场的GPS转发信号跟踪系统方案利用转发的GPS信号测定弹道 无线电外测一种经济效益很高的校准无线电外测系统的方法—卫星校准法用跟踪卫星的方法对陆上脉冲雷达进行自校准阿里安运载火箭飞行试验用的C波段雷达的卫星校准用GEOS一3卫星校准C波段雷达的研究C波段雷达校准及其在GEOS一I计划中的应用无线电外弹道测量系统校准卫星文献目录双向相干通信系统中的信道误差美国陆军白沙导弹靶场动目标分辨技术的开发模糊距离研究报告用距离游标法提高外测能力白沙导弹靶场的…     

模糊C均值算法在机载PD雷达杂波跟踪中的应用

介绍一种适用于机载PD雷达的杂波跟踪技术，结合机载PD雷达杂波分布特征和模糊C均值算法的特点，将模糊C均值算法用于杂波跟踪，给出了相应的算法流程，并提出了一种确定初始模糊隶属度的方法，经仿真数据验证，取得了满意的结果。     

问与答

白杨-M问:1、什么是脉冲多普勒雷达?答:脉冲多普勒雷达就是工作在脉冲波形下的一种多普勒雷达,其工作原理是对脉冲列信号进行频谱分析,并对其单根谱线进行滤波,以测得目标的径向速度和距离。与一般时域检测的脉冲体制雷达不同之处是,脉冲多普勒雷达是频域检测,对回波脉冲列进行频谱分析,利用运动目标的回波信号具有多普勒频移的特点,将     

基于数字包络检波的RNSS通道时延标定方法

提出一种采用数字处理的时延测试方法,用于对导航卫星导航信号发射通道分数码片时延的精确测量。该方法是通过高速A/D（模/数）转换器,对导航卫星下行的BPSK（二进制相移键控）信号和卫星导航秒脉冲进行双通道采样,读取采样数据并进行数据处理。根据秒脉冲信号触发门限上升沿确定时延测量起点,对BPSK采样数据进行平方律检波,获取码片换相点,计算换相点和秒脉冲之间的分数码片时延,并进行滤波器时延校准,从而得到导航卫星发射链路的分数码片时延,该方法不需要进行伪随机信号的捕获和跟踪,测量精度主要取决于采样器采样率。通过在测试中使用一根校准电缆对该方法进行验证,验证结果表明,采用本文提出测试方法的测量误差优于0.3ns。     

固体火箭喷焰对雷达测量信息的影响

从某系列四发固体火箭成功发射时的雷达跟踪测量数据发现：二级发动机关机前约３０秒存在测量数据随机误差由偏大、超差、直到严重超差的现象。本文给出了多种数据,并据此认为：其原因是各种射频信号通过具有高温弱等离子体的火箭喷焰区时,引起了衰减、相移和调幅调相噪声,给外弹道的无线电测量带来误差,且信号穿过喷焰区的路径越长,影响越大。     

数值法修正雷达高仰角动态滞后误差研究

脉冲雷达在高仰角跟踪过程中存在不容忽视的动态滞后误差,该类误差的存在严重影响到雷达数据处理和弹/轨道精密确定。目前外测数据处理领域采用的基于误差电压和定向灵敏度的动态滞后误差修正模型,修正效果不理想。本文提出了一种用数值法修正雷达高仰角动态滞后误差的方法,并用任务实测数据进行了模型验证,结果显示这种方法能有效地降低动态滞后引起的误差。     

脉冲测量雷达卫星标定方法研究

对脉冲测量雷达卫星标定方法的原理和工程应用等问题进行了研究,提出了标定模型和方法,分析了雷达跟踪能力和卫星定轨保障等工程应用问题,并对标定效果进行了仿真验证。     

基于检测前跟踪的超视距雷达微弱目标检测方法

天波超视距雷达（over-the-horizonradar，OTHR）通过快速傅立叶变换（FFr）实现相干积累，再利用常规的方法进行目标检测。但这种方法在弱目标、低信噪比的情况下效果并不好。本文提出了一种基于检测前跟踪（track-before-detect，TBD）的OTHR弱目标检测方法，利用数学形态学对每帧弱目标回波信号进行滤波，再通过动态规划方法进行检测。仿真结果表明，该方法能够有效地提高OTHR对弱目标的检测能力，运算效率高，实用性强。     

宽带信号去斜脉冲压缩处理方法的研究

宽带信号广泛应用于雷达、导航和卫星通讯等领域。宽带信号的传统接收处理方法主要是采用匹配滤波或子带分割技术。本文用去斜脉冲压缩处理方法处理宽带信号,给出了具体的实现结构和改进措施,分析了如何选择系统的信号采样频率,同时还给出了脉压波形的仿真结果及性能分析。实验表明:对中心频率为9.5GHz、带宽1.3GHz、脉冲宽度30μs的宽带线性调频信号,采用该方法处理只需90MHz采样数据率,大大降低了数据采集的难度。     

动态时频谱分析、探测和跟踪的随机有限集法

动态出现和消失多分量信号的时频分析问题一直是非平稳信号处理的难点之一。为此，提出了一种分析、探测和跟踪多分量信号的随机有限集法。该算法利用时频变换，如短时傅里叶变换或自适应谱估计法，以及多项式预测模型，将多分量信号的时频分析问题归纳成可利用随机有限集进行多目标追踪的问题。分析表明：借助于提出的初始权重赋值算法，以及谱分量幅度和频率的联合似然函数，就可利用高斯混合概率假设密度滤波器来实现对动态时频谱的分析、探测和跟踪。在仿真实验中，所提算法有效提升了动态时频谱的跟踪精度，其对微弱时频谱分量的探测能力，以及对载频差异的分析能力均优于文献报道的算法。     

Multiple model particle flter track-before-detect for range ambiguous radar

The middle pulse repetition frequency（MPRF）and high pulse repetition frequency（HPRF）modes are widely adopted in airborne pulse Doppler（PD）radar systems,which results in the problem that the range measurement of targets is ambiguous.The existing data processing based range ambiguity resolving methods work well on the condition that the signal-to-noise ratio（SNR）is high enough.In this paper,a multiple model particle flter（MMPF）based track-beforedetect（TBD）method is proposed to address the problem of target detection and tracking with range ambiguous radar in low-SNR environment.By introducing a discrete variable that denotes whether a target is present or not and the discrete pulse interval number（PIN）as components of the target state vector,and modeling the incremental variable of the PIN as a three-state Markov chain,the proposed algorithm converts the problem of range ambiguity resolving into a hybrid state fltering problem.At last,the hybrid fltering problem is implemented by a MMPF-based TBD method in the Bayesian framework.Simulation results demonstrate that the proposed Bayesian approach can estimate target state as well as the PIN simultaneously,and succeeds in detecting and tracking weak targets with the range ambiguous radar.Simulation results also show that the performance of the proposed method is superior to that of the multiple hypothesis（MH）method in low-SNR environment.     

Polish radar technology

Polish radar research and development since 1953 is reviewed, covering the development and production of surveillance radars, height finders, tracking radars, air traffic control (ATC) radars and systems, and marine and Doppler radars. Some current work, including an L-band ATC radar for enroute control, a weather channel for primary surveillance radar, signal detection in non-Gaussian clutter, adaptive MTI filters and postdetection filtering, and a basic approach to radar polarimetry, is examined.<>     

Probability of Pulse Coincidence in a Multiple Radar Environment

Elementary probability theory is used to develop three formulas for the probability of two or more pulses being coincident at an observer's aircraft position in a multiple radar environment. The first formula is for nonscanning tracking type radars with different pulsewidths (PWs) and pulse repetition frequencies (PRFs), the second is for generically identical nonscanning radars with similar PWs and PRFs, and the third is for scanning type radars such as air search radars with similar PWs and PRFs. The probability of coincidence is related to the mean-time-between-coincidences (MTBC) and to the average coincidence rate. Two sample problems are given.     

Signal-to-Noise Ratio Calculations in Pulse and Pulse Doppler Radars

In low pulse-repetition frequency (PRF) pulse radars, signal-to-noise ratio (SNR) is usually calculated on a per pulse basis and this value is then multiplied by the number of pulses integrated to obtain the SNR for a given duration of target illumination. In high PRF pulse Doppler radars, SNR is usually calculated by using the centerline power of the transmitted signal spectrum as the target return power because the centerline is kept in the receiver and returns of the PRF lines are notched out [1]. We show here that both methods of SNR calculations are entirely equivalent for matched transmit-receive radar systems.     

Medium PRF Performance Analysis

A discussion of various types of x-band airborne radars is presented together with their systematic development through the years to the present time. Starting with simple, low pulse-repetition frequency (PRF) radars for measuring radar-target range, airborne radar development proceeded with more sophisticated high PRF Doppler radars where radar-target range and range rate were measured simultaneously. The use of Doppler (frequency) in signal processing allowed the separation of moving from nonmoving targets (ground), enabling the detection of moving targets in the presence of ground clutter. More recent developments in waveform generation and selection has resulted in the development of medium PRF radars, whereby a greater degree of tactical flexibility in target detection is achieved by combining the desirable features of both low and high PRF radars. Part of the available literature gives an overview, together with a specific example of the design and performance of an airborne medium PRF radar. Here, however, the systematic evolution of these radars is emphasized and the necessary theoretical background is developed for their performance calculations. Modern day airborne radars may be equipped with all three modes of operation, low, medium, and high PRF, allowing the operator to utilize the mode best suited for the tactical encounter. Low PRF and high PRF radars have been described elsewhere and are given here primarily for the sake of completeness and for the necessary background for developing medium PRF radar equations. They are also needed for developing the reasons why medium PRF radars came into being.     

Senrad: an advanced wideband air-surveillance radar

The generic characteristics and performance of an experimental long-range air-surveillance radar, known at the Naval Research Laboratory as Senrad, is described. Its distinguishing feature is that it can operate with simultaneous transmissions over a very wide bandwidth-from 850 to 1400 MHz. The technology and type of experimental radar equipment employed are discussed and examples are given of its performance capabilities obtained by means of very wideband operation. The unusually wide bandwidth of this radar allows 1) improved detection and tracking performance because of the absence of the nulls that are common in the antenna elevation radiation-pattern of a single-frequency radar; 2) moving target indication (MTI) without loss of targets due to blind speeds and without the need for multiple PRFs (pulse repetition frequencies); 3) accurate height finding with a fan-beam radar by taking advantage of the multipath time difference as a function of target height; 4) a form of limited target recognition based on high range-resolution; and 5) a reduction of the effectiveness of electronic countermeasures that can seriously degrade more narrowband radars     

Ukraine institute of radio astronomy high-resolution radars

A review is given of recent activities undertaken in the Institute of Radio Astronomy of the National Academy of Sciences of Ukraine for the development of high-resolution radars. The radars developed include 95- and 36-GHz cloud radars and an airborne, Ku-band SAR radar system. They are capable to perform real-time, high-resolution measurements. The set-up of these instruments, the novel technical solutions, and the signal processing technique introduced are discussed. The results obtained with such instruments during measurement campaigns are presented as well.     

关于隐身目标检测与跟踪的几点思考

隐身武器装备的出现和发展对传统雷达的检测与跟踪性能构成了严峻的威胁。首先,分析了隐身目标检测与跟踪中存在的一些关键问题;然后,对高机动隐身目标、多隐身目标、机载高脉冲重复频率雷达的多隐身目标等检测与跟踪问题进行了初步的探讨,并提出了一些可行的解决方案。