{"id":1354,"date":"2013-07-11T11:04:08","date_gmt":"2013-07-11T11:04:08","guid":{"rendered":"http:\/\/electronicsmaker.com\/?p=1354"},"modified":"2013-07-11T11:11:55","modified_gmt":"2013-07-11T11:11:55","slug":"wideband-radar-system-testing","status":"publish","type":"post","link":"https:\/\/electronicsmaker.com\/wideband-radar-system-testing","title":{"rendered":"Wideband Radar System Testing"},"content":{"rendered":"

Testing wideband RADARs with complex signal types poses potential challenges due to continually increasing modulation and analysis bandwidths. This paper will present how wide bandwidth RADAR complex signals can be created and analyzed with high precision using the modern test systems.<\/em><\/strong><\/span><\/h2>\n

RADARs stands for \u201cRA<\/strong>dio D<\/strong>etection A<\/strong>nd R<\/strong>anging\u201d which enable a certain class of objects, termed as \u201cTargets\u201d to be \u201cseen\u201d; which are, detected and located; at distances far beyond those at which they could not be distinguished by the unaided eye. Given the broad range of applications, a variety of radar types and technologies have emerged to meet unique needs viz. CW, Simple Pulse, Pulse Compression, Mono-pulse, Phased Array, Synthetic Aperture, 3D, MIMO, etc. With the modernization of Electronic Warfare (EW) systems modern RADARs are becoming more intelligent and smart to adapt to work in the presence of modern Electronic Counter Measures (ECM) systems, like jammers. \u00a0Sophisticated phased-array radars may have thousands of transmit\/receive (T\/R) modules operating in tandem and may use a variety of sophisticated techniques to improve performance: side-lobe nulling, staggered pulse repetition interval (PRI), frequency agility, real-time waveform optimization, wideband chirps, and target recognition capability. Multiple-Input and Multiple-Output (MIMO) radar has generated interest due to its capability of improved target detection and target discrimination potential. Testing such wideband RADARs with complex signal types poses potential challenges due to continually increasing modulation and analysis bandwidths. This paper will present how wide bandwidth RADAR complex signals can be created and analyzed with high precision using the modern test systems.<\/p>\n

Introduction<\/strong><\/p>\n

The Principle of RADAR is its ability to gather information about an unknown object primarily called as Target. This information is targets\u2019 presence, distance, direction, type, location and speed. This is normally achieved by processing reflected Radio Frequency (RF) signals from the targets. These types of RADARs are commonly known as primary RADARs. In other cases RADARs transmit a radio frequency (RF) and its reflation form the target is processed. These types of RADARs are known as secondary RADARs. For the rest of the paper we will concentrate on secondary RADAR type.<\/p>\n

There are categorized in various ways based upon their applications and one way is to group them based upon their performance<\/p>\n

    \n
  1. Military (A\/D) \u2013Aircraft (airborne), Ships, ground-based. These radars are used for identifying targets, moving or stationary.<\/li>\n
  2. Commercial\u2013Police (speed detection), weather, automatic door opener, automobiles (backup aides, collision avoidance).<\/li>\n<\/ol>\n

    As compared to commercial RADARs, military radars possess higher design and manufacturing challenges as they require very high performance which may include:<\/p>\n

    \u2192\u00a0Higher frequency<\/p>\n