Flyable fiber-optic radar target generator

Airborne radar relies on Built-in-Test (BIT) for fault detection, fault isolation and system calibration. The capability of BIT is often limited by space, weight, size and cost considerations. Furthermore, the radar does not have a test target that will allow BIT to perform in flight, closed-loop functional test of the complete radar system. This paper describes a fiber-optic based radar test target unit that provides a delayed replica of the transmitted radar signal. The unit will intercept a small amount of radar-transmitted energy, delay it in the fiber, then feed it back into the radar producing a calibrated “echo” at a predetermined radar range. The unit can be installed as part of the airborne radar. The details on the design and testing of a proof-of-concept unit are also given     

A megawatt power millimeter-wave phased-array radar

This article describes the design and development of a multi-megawatt radar “Ruza,” having a large mechanically steered, millimeter-wave, phased-array antenna     

Stochastic-constraints method in nonstationary hot-cluttercancellation. I. Fundamentals and supervised training applications

This paper considers the use of spatio-temporal adaptive array processing in over-the-horizon radar (OTHR) and airborne radar applications in order to remove nonstationary multipath interference, known as “hot clutter”. Since the spatio-temporal properties of hot clutter cannot be assumed constant over the coherent processing interval (CPI), conventional adaptive techniques fail to provide effective hot-clutter mitigation without simultaneously degrading the properties of the backscattered radar signals, known as “cold clutter”. The approach presented incorporates multiple “stochastic” (data-dependent) constraints to achieve effective hot-clutter suppression, while maintaining distortionless output cold-clutter post-processing stationarity     

Improved adaptive clutter cancellation through data-adaptivetraining

Adaptive array algorithms based on sample matrix inversion (SMI) require the availability of a secondary data set to “train” the adaptive filter. Numerous data-independent rules have been proposed for selecting this training data. However, such rules often perform poorly in inhomogeneous environments. We present data-adaptive methodologies for selecting the training data. The techniques, called “Power Selected Training” and “Power Selected Deemphasis”, use measurements of the interference environment to select training data. This work describes these algorithms and their performance on recorded radar data     

Space-borne imaging

Radar's ability to “see” through darkness, clouds and smoke and to cover large areas gives it unique power as a global remote-sensing tool. Imaging radar evolved from its beginnings 50 years ago through airborne research to space-borne systems. Operational space-borne systems of today are capable of generating global geological and topographic maps, using advanced synthetic aperture radar techniques such as polarimetry and interferometry. The future holds great promise for increased use of imaging radar for remote sensing, including, more accurate elevation mapping, natural hazards monitoring, soil moisture mapping and biomass estimation     

Ultra-wideband ground-penetrating radar for the detection of buriedmetallic mines

The suitability of ultra-wideband ground-penetrating radar as a tool for the detection of buried metallic mines is explored in this paper. The analysis centers around a 200-800 MHz, dual-polarized ground penetrating radar (GPR) designed and built by SRI International. The analysis consisted of fusing the images from the dual polarizations into a single image to enhance the target objects and suppress clutter. Results are shown for several variations of a Mahalanobis-based fusion technique, and “soft decision” minefield detection results based upon Monte Carlo statistical techniques are also presented. Although relatively few scenes were analyzed, these results show that the dual-polarized GPR is potentially very effective at finding buried mines and minefields     

An experiment with an S-band radar using pulse compression andrange sidelobe suppression for meteorological measurements

A major technology barrier to the application of pulse compression for the meteorological functions required by a next generation ATC radar is range/time sidelobes which mask and corrupt observations of weak phenomena occurring near areas of strong extended meteorological scatterers. Techniques for suppressing range sidelobes are well known but without prior knowledge of the scattering medium's velocity distribution their performance degrades rapidly in the presence of Doppler. Recent investigations have presented a “doppler tolerant” range sidelobe suppression technique. The thrust of the work described herein is the extension of previous simulations to actual transmitted dispersed/coded waveforms using the S-band surveillance radar located at Rome Laboratory Surveillance Facility. The objectives of the experiment are: 1) to extend the verification of the simulation of the Doppler tolerant technique; and 2) to demonstrate that the radar transmitter, waveform generator, and receiver imperfections do not significantly degrade resolution, performance or reliability of meteorological spectral moment estimates     

Surveillance through walls and other opaque materials

The Department of Defense (DoD) has funded a dazzling array of “high tech” solutions for many of the problems facing our military forces. Many of these “solutions” have been effective for long range mass destruction but have not been applicable for the close-in hand-to-hand combat that is on our streets. Our goal at the Hughes AET Center has been to convert “high tech” DoD capabilities into cost effective tools to help law enforcement agencies do their jobs better. Surveillance systems presently used by law enforcement officers make extensive use of television, infrared and other Line-of-Sight (LOS) surveillance systems. However, these systems cannot tell what is happening on the other side of a wall, behind bushes, around the corner, in the dark or through a dense fog. A new sensor has been developed that uses technology developed by the DoD for missile warhead fuzing. This small, light weight, low power “Radar” is based upon the fact that radio waves can penetrate nonmetallic materials. This new surveillance capability can help provide information about what is in a wall, ceiling or floor or on the other side of a door or concrete wall. Real field scenarios are used in this paper to show how this radar works and how field users can tell if someone is moving inside a building, even from remote locations     

Support vector machines for SAR automatic target recognition

Algorithms that produce classifiers with large margins, such as support vector machines (SVMs), AdaBoost, etc, are receiving more and more attention in the literature. A real application of SVMs for synthetic aperture radar automatic target recognition (SAR/ATR) is presented and the result is compared with conventional classifiers. The SVMs are tested for classification both in closed and open sets (recognition). Experimental results showed that SVMs outperform conventional classifiers in target classification. Moreover, SVMs with the Gaussian kernels are able to form a local “bounded” decision region around each class that presents better rejection to confusers     

Circular array STAP

Traditionally, space-time adaptive processing (STAP) for airborne early warning (AEW) radar has been applied to uniform linear arrays (ULAs). However, when considering the overall radar system, electronically scanned circular arrays have advantages: a better combination of even and continual angular and temporal coverage, and mechanical simplicity because it does not need to rotate. This paper answers the question “How well does STAP perform when applied to a circular array?” This paper shows that for the AEW mission, circular arrays are indeed STAP compatible. However, when conventional STAP algorithms are used there may be a small loss in performance when compared with a ULA. With some care in the choice and implementation of the STAP algorithm, the majority of the degradation is at close ranges, where the target returns are relatively strong. At long ranges performance is barely affected. A STAP algorithm which compensates for the circular array environment and provides better performance than existing algorithms is presented     

Integrated precision SAR targeting: a SAR targeting simulation

Operational deficiencies exist in the current ability to perform high resolution synthetic aperture radar (SAR) targeting for precision strike missions in difficult electronic countermeasure (ECM) and anti-aircraft environments. Increasingly sophisticated enemy defenses require that fire control information be derived from highly maneuverable aircraft trajectories rather than traditional straight-and-level flight. In addition, target area aspect information is needed to determine optimal attack approaches. These imaging and targeting conditions impose severe performance requirements on the sensor aircraft motion compensation system (MCS), and dictate the need for sophisticated algorithms to counteract ECM threats. This paper describes the development of a user friendly “Design Tool” for modeling and analysis of airborne radar system performance for SAR imaging and Precision SAR Targeting     

Millimeter wave safety warning system for in-vehicle signing

Georgia Tech Research Institute (GTRI) has developed a millimeter wave safety warning system for in-vehicle signing for use in the nation's Intelligent Transportation System (ITS, formerly IVHS). The Safety Warning System TU (SWS) utilizes a homodyne radar that operates at 24.1 GHz as both a radar and a system to transmit highway safety messages. The warning message is received by a police radar detector or stand-alone safety warning receiver without radar detector capability. When the message is received, it is displayed to the driver via an alphanumeric light emitting diode (LED) display. The message can also be announced by a voice synthesizer internal to the receiver or by a flashing LED labeled “SWS.” The system is designed to inform the driver that he or she is being overtaken by a police car or emergency vehicle in motion. When the police car or emergency vehicle stops, the radar transmitter senses that the platform is no longer moving and the system automatically changes its message to warn approaching drivers of a stationary hazard ahead. A second safety warning transmitter deployment concept is to mount the unit near the highway at a fixed location. The fixed location SWS is designed to be programmable and transmit any one of 64 fixed text messages     

Battlefield awareness via synergistic SAR and MTI exploitation

“Battlefield awareness” is critical to the success of future military operations. Existing and new sensor platforms will provide the necessary surveillance data; DARPA is developing the systems needed to turn the sensor data into meaningful information for the commanders. A central thrust of these efforts exploits the synergistic relationship between SAR and MTI radar. Used together, they offer comprehensive coverage of the battlefield     

“定制”与“广义”概念下的指尖密封结构优化

 为了获得高性能的指尖密封结构型式，根据指尖密封的结构组成特点，提出了“定制”型线和“广义”型线概念下的指尖密封结构优化策略，以及反映指尖密封基本组成特征和具有“单元叠加”功能的最小优化单元。通过采用统一优化法和分步优化法对两类指尖密封结构的多目标优化问题进行了优化分析，研究结果表明，“定制”型线指尖密封结构优化和 “广义”型线指尖密封结构优化的策略和方法，可以达到同步降低指尖密封迟滞率和综合刚度的多目标优化目标，是获得具有良好综合性能的指尖密封结构的有效途径。从工程意义上讲，“广义”型线指尖密封结构优化技术更具选择指尖密封性能优化取向和程度的优势。     

复杂目标高频区 RCS 的实时计算

提出一种在安装图形加速卡的高性能微机上实时计算复杂目标高频区雷达散射截面（RCS）的方法。该方法利用了“图形电磁计算（GRECO）”的新技术。目标用G2Catmul-om（C-R）几何样条模拟,由图形加速卡硬件完成遮挡、消隐运算,运用Phong光照模型着色渲染目标可见表面,应用物理光学（PO）、等效电流法（MEC）、物理绕射理论（PTD）及阻抗边界条件（IBC）等方法计算目标高频区雷达散射截面（RCS）.     

“Dakota Sun”-the next generation solar powered racingvehicle

Based on the experience gained from Sunrayce '95, the Solar Motion Team has made many changes to the design of the next generation solar car. These changes have resulted in a vehicle that is very different from the “Solar Rolar”, The Dakota Sun is a three wheeled vehicle with separate cab and solar array. This design allows for improved aerodynamics, decreased weight, lower rolling resistance, and ease of manufacture compared to the four wheeled catamaran used in the last race. However, this design sacrifices total enclosed wheel base area, additional room for components, and added power from side solar panels, The major objectives for the team's redesigned Sunrayce '97 entry are: systems integration; decrease the weight of the car; decrease aerodynamic drag; more efficient use of available energy; and increased driver safety. The team has set a standard to use the latest available technology. Although this increases the complexity of the components, by using a systems engineering approach the “Dakota Sun” has evolved into a more integrated vehicle. This philosophy of integrated design has resulted in great improvements in mechanical design and manufacturing techniques, as well as electrical innovations. The major design changes evident from the original Sunraycen '95 vehicle are the result of an evolutionary design process that has produced the highly competitive Sunraycel '97 design outlined in this article     

平衡交通运输网络设计的最优化数学模型

分析了影响交通运输网络发展的因素,总结了课题研究的程序。综合运用了“系统最优原理”和“用户最优原理”,给出了多目标、多运输方式与运送对象的平衡交通网络设计的一般表达式。系统最优与用户最优方法同时又能用于研究国家和省级铁路、公路系统的交通运输问题。文中对这个非凸规划问题给出局部最优解的算法。     

Receiver antenna scan rate requirements needed to implement pulsechasing in a bistatic radar receiver

Pulse chasing is a technique implemented by a bistatic or multistatic radar system that allows rapid and efficient search of a desired volume of space whereby the receiving antenna is made to follow or “chase” the transmitted pulse as it travels radially outward from the transmitter antenna. An expression for receiver antenna scan rate requirements is derived that corrects an error in the prior literature. The results give significantly reduced scan rates in the forward scatter region near the baseline showing that pulse chasing is more easily implemented using conventional analog beamformer phased array technology than was suggested by prior work