از انواعی از رادارها هستند که بدون اینکه از خود تشعشعاتی صادر کنند می توانند اهداف را شناسایی و ردیابی نمایند.

» معرفی :

سیستمهای راداری متداول از یک بخش فرستنده و دریافت کننده تشکیل می شوند که اغلب از یک آنتن برای ارسال و دریافت استفاده می کنند ، یک سیگنالی پالسی ارسال می شود و زمان برخورد آن به هدف و دریافت آن این اجازه را می دهد تا فاصله و مشخصات هدف محاسبه شود.

در سیستم های رادار پسیو (passive radar system) هیچ نوع فرستنده اختصاصی وجود ندارد در عوض سیستم دریافت کننده از فرستنده سومی در محیط بهره می گیرد ، و اختلاف زمان بین سیگنالی که مستقیما از فرستنده دریافت میشود و سیگنالهایی را که در اثر تشعشع دریافت می شود را اندازه می گیرد. این کار اجازه می دهد تا وضعیت هدف و تحرک آن مشخص گردد(bistatic range) .همچنین در فاصله ایستا ، یک رادار پسیو  به صورت رمز تغییرات داپلری بازتاب و همچنین جهت حضور را نیز نمایان می کند.

این مشخصات کمک می کند که مکان ،جهت حرکت و سرعت هدف توسط کامپیوتر محاسبه شود. در برخی موارد ،چندین فرستنده و یا گیرنده بکار می روند تا چندین محاسبه مستقل از فواصل  bistatic داشته باشیم ،تغییر تن صدای خودرو یا موتور جنگنده  در نهایت دقت در یافتن هدف نهایی را ساده تر می کند.

اصطلاح "رادارهای پسیو" گاهی اوقات به صورت اشتباه بکار می روند برای سنسورهای پسیوی که توسط امواج رادیویی ارسالی هواپیماها را شناسایی می کنند(مثل رادارها،ارتباطات ،یا دستگاه کشف و رمز خودکار مکالمات) .اما ، این سیستم ها از انرژی بازتابی استفاده نمی کنند و باید آنها را سیستم های ESM نامگذاری نمود. نمونه های شناخته شده ی آنها عبارتند از : سیستمهای TAMARA and VERA چک و اسلواکی و سیستمهای Kolchuga کشور اکراین .

» تاریخچه :

تدبیر ساخت رادارهایی که آشکارسازی را بوسیله امواجی که از هدف ساطع می شوند انجام می دهند ایده جدیدی نیست.اولین آزمایشات در سال 1935 توسط رابرت واتسون وات(Robert Watson-Watt) در انگلستان صورت پذیرفت . او توانست یک بمب افکن را توسط امواج کوتاه در 12 کیلومتری تشخیص دهد.

رادارهای اولیه همگی ایستا(bistatic) بودند زیرا تکنولوژی به اندازه ای پیشرفت نکرده بود تا آنتن را قادر نماید تا از فرستندگی به گیرندگی سوئیچ نماید. کشورهای زیادی از سیستمهای ایستا(bistatic) در شبکه های دفاع هوایی استفاده می کردند.

به صورت مثال در اوایل سال 1930  انگلستان سیستم خانه زنجیره ای (CHAIN HOME) را راه اندازی کرد. فرانسوی ها  از یک رادار ایستای (bistatic)  موج دائم (CW) در سیستمی به نام(fence) استفاده کردند. شوروی  سیستم (RUS-1) را ساخت و ژاپن(Type A) را ساخت.

آلمانی ها از سیستم(bistatic) در طول جنگ جهانی دوم استفاده کردند. این سیستم صنایع (Kleine Heidelberg) نامیده می شد که مثل دریافت کننده های ایستا عمل می کرد و از سیستم داخلی رادارهای انگلیسی برای آشکار نمودن هواپیماها در بخش های جنوبی دریای شمال استفاده می کرد .

در سال  1936 رادارهای تک ایستایی(Bistatic) راهی را پیش رو نهاد برای استفاده از سیستم های راداری دو ایستایی(monostatic) با استفاده از یک بهبود دهنده . سیستم های monostatic بسیار راحت تر بودند و آنها مشکلات سیستم های تک ایستایی را حل نمودند که بوسیله فرستنده ها و گیرنده های جدا تعریف می شد. همچنین تجهیزات سیستم های راداری هواپیماها کوچکتر گردید . در سال 1950 سیستمهای(bistatic) با خواص رادار پراکنده مجددا معرفی شدند ، براستی اولین استفاده از اصطلاح (bistatic) توسط (Seigel) در سال 1955 در گزارشش که درباره این خواص بود مطرح گردید.

آزمایشات در ایالات متحده به توسعه سیستم های (bistatic) کمک نمود،طراحی رادار (AN/FPS-23 fluttar) که یک (DEW) به معنای یک هشدار دهنده فاصله دور است در آمریکای شمالی صورت گرفت . این رادار یک موج مداوم  (bistatic) داشت که در 1955 ساخته شده بود و وظیفه آن آشکار سازی نفوذ دشمن توسط بمبرهایی که در ارتفاع پایین پرواز می کنند بود . رادارهای فلوتار (fluttar radars) برای پوشش شکاف های ارتفاع پائین و رادراهای جستجو گر (monostatic surveillance radars) به جای دیده بان ها استفاده می شدند. رادارهای فلوتار به مدت 5 سال در شرکت خط شبنم(DEW line) در حال توسه و ساخت بودند .

» اصول اولیه کار

در رادارهای معمولی، زمان ارسال پالس و دریافت آن کاملا شناخته شده است و به رادار این اجازه را می دهد تا فاصله هدف به راحتی محاسبه شود و توسط یک فیلتر تطابق درصد سیگنال به نویز را مشخص نماید . یک رادار پسیو هیچ اطلاعاتی را به طور مستقیم دریافت نمی نماید ، از این رو باید از یک کانال اختصاصی (که کانال منبع نامیده می شود)استفاده نماید برای هر ارسال کننده ای که وجود دارد .

یک رادار پسیو از مراحل زیر استفاده می نماید :

منطقه تحت پوشش را برای دریافت امواج توسط دریافت کننده های دیجیتالی بدون نویز جستجو می نماید .

تولید امواج دیجیتال برای تشخیص جهت دریافت امواج و فاصله ارسال شده و قدرت منبع ارسال کننده .

فیلترینگ انطباقی برای جداسازی هر سیگنال مستقیم ناخواسته در محدوده تجسس .

آماده سازی سیگنال مشخص شده برای ارسال کننده .

رابطه ضربدری برای کانال منبع با کانال های تجسس  برای مشخص کردن رنج بای استاتیک و داپلر هدف.

آشکار سازی با استفاده از طرح  میزان آلارم خطا (constant false alarm rate (CFAR))

ارتباط و پیگیری هدف در فضای داپلر تحت پوشش که به نام پیگیری خطی(line tracking) شناخته شده است .

ارتباط و ترکیب پیگیری خطی از هر ارسال کننده به شکل ارزیابی نهایی از موقعیت و سمت و سرعت یک هدف به نمایش در می آید.

» سیستم دریافت

از آنجا که این نوع از رادارها به پالس های امواج دریافتی گوش می دهند و نتیجه را به صورت نهایی در اختیار قرار می دهند پس سیستم دریافت باید دارای مشخصه نویز پایین ، رنج فعالیت بالا و رنج خطی بالا باشد . بنابراین این سیستم بسیار به نویز حساس است . رادارهای پسیو دریافت کننده های دیجیتالی بسیار حساسی هستند که یک خروجی دیجیتال و یک موج نمونه می دهند.

» شکل موج دیجیتال

اکثر سیستم های رادار پسیو از مجموعهء چند آنتن و عناصر دیجیتال کننده تشکیل شده اند. این موضوع به ما اجازه می دهد تا جهت امواج رسیده به رادار محاسبه شوند .

» مزایا و معایب این نوع رادارها

مزایا :

پایین بودن هزینه آماد

پایین بودن هزینه نگهداری و منتنس به خاطر نداشتن ارسال کننده

پنهانکاری راداری ، به علت نداشتن امواج ارسالی

اندازه کوچکتر نسبت به رادارهای اکتیو

امکان مقابله و ردیابی جنگنده های پنهانکار

قابلیت به روز کردن سریع اطلاعات راداری

بسیار سخت و غیر قابل نفوذ و هک شدن(jamming)

غیر قابل ردیابی در مقابل موشک های ضد تشعشع

 معایب :

 هنوز این تکنولوژی کامل نیست

در صورت زیاد بودن نویز محیط قابل اعتماد نیست

پیچیده بودن سیستم کاری

عملکرد دو بعدی (2D)

برای کسب اطلاعات بیشتر به منبع زیر مراجعه بفرمایید.

Passive radar

Passive radar systems (also referred to as passive coherent location and passive covert radar) encompass a class of radar systems that detect and track objects by processing reflections from non-cooperative sources of illumination in the environment, such as commercial broadcast and communications signals. It is a specific case of bistatic radar, the latter also including the exploitation of cooperative and non-cooperative radar transmitters.

Introduction

Conventional radar systems comprise a collocated transmitter and receiver, which usually share a common antenna to transmit and receive. A pulsed signal is transmitted and the time taken for the pulse to travel to the object and back allows the range of the object to be determined.

In a passive radar system, there is no dedicated transmitter. Instead, the receiver uses third-party transmitters in the environment, and measures the time difference of arrival between the signal arriving directly from the transmitter and the signal arriving via reflection from the object. This allows the bistatic range of the object to be determined. In addition to bistatic range, a passive radar will typically also measure the bistatic Doppler shift of the echo and also its direction of arrival. These allow the location, heading and speed of the object to be calculated. In some cases, multiple transmitters and/or receivers can be employed to make several independent measurements of bistatic range, Doppler and bearing and hence significantly improve the final track accuracy.

The term "passive radar" is sometimes used incorrectly to describe those passive sensors that detect and track aircraft by their RF emissions (such as radar, communications, or transponder emissions). However, these systems do not exploit reflected energy and hence are more accurately described as ESM systems. Well known examples include the Czech TAMARA and VERA systems and the Ukrainian Kolchuga system.

History

The concept of passive radar detection using reflected ambient radio signals emanating from a distant transmitter—is not new. The first radar experiments in the United Kingdom in 1935 by Robert Watson-Watt demonstrated the principle of radar by detecting a Handley Page Heyford bomber at a distance of 12 km using the BBC shortwave transmitter at Daventry.

Early radars were all bistatic because the technology to enable an antenna to be switched from transmit to receive mode had not been developed. Thus many countries were using bistatic systems in air defence networks during the early 1930s. For example, the British deployed the CHAIN HOME system; the French used a bistatic Continuous Wave (CW) radar in a "fence" (or "barrier") system; the Soviet Union deployed a bistatic CW system called the RUS-1; and the Japanese developed a bistatic CW radar simply called "Type A".

The Germans used a passive bistatic system during World War II. This system, called the Kleine Heidelberg device, was deployed at seven sites (Limmen, Oostvoorne, Ostend, Boulogne, Abbeville, Cap d'Antifer and Cherbourg) and operated as bistatic receivers, using the British Chain Home radars as non-cooperative illuminators, to detect aircraft over the southern part of the North Sea.

Bistatic radar systems gave way to monostatic systems with the development of the synchronizer in 1936. The monostatic systems were much easier to implement since they eliminated the geometric complexities introduced by the separate transmitter and receiver sites. In addition, aircraft and shipborne applications became possible as smaller components were developed. In the early 1950s, bistatic systems were considered again when some interesting properties of the scattered radar energy were discovered, indeed the term "bistatic" was first used by Seigel in 1955 in his report describing these properties.

Experiments in the United States led to the deployment of a bistatic system, designated the AN/FPS-23 fluttar radar, in the North American Distant Early Warning (DEW) Line. The fluttar radar was a CW fixed-beam bistatic fence radar developed in 1955 to detect penetration of the DEW line by low-flying bombers. The fluttar radars were designed to fill the low-altitude gaps between SENTINEL monostatic surveillance radars. Fluttar radars were deployed on the DEW line for approximately five years.

The rise of cheap computing power and digital receiver technology in the 1980s led to a resurgence of interest in passive radar technology. For the first time, these allowed designers to apply digital signal processing techniques to exploit a variety of broadcast signals and to use cross-correlation techniques to achieve sufficient signal processing gain to detect targets and estimate their bistatic range and Doppler shift. Classified programmes existed in several nations, but the first announcement of a commercial system was by Lockheed-Martin Mission Systems in 1998, with the commercial launch of the Silent Sentry system, that exploited FM radio and analogue television transmitters.

Typical illuminators

Passive radar systems have been developed that exploit the following sources of illumination:

Analog television signals

FM radio signals

GSM base stations

Digital audio broadcasting

Digital video broadcasting

Terrestrial High-definition television transmitters in North America

Satellite signals have generally been found to be inadequate for passive radar use: either because the powers are too low, or because the orbits of the satellites are such that illumination is too infrequent. The possible exception to this is the exploitation of satellite-based radar and satellite radio systems.

Principle

In a conventional radar system, the time of transmission of the pulse and the transmitted waveform are exactly known. This allows the object range to be easily calculated and for a matched filter to be used to achieve an optimal signal-to-noise ratio in the receiver. A passive radar does not have this information directly and hence must use a dedicated receiver channel (known as the "reference channel") to monitor each transmitter being exploited, and dynamically sample the transmitted waveform. A passive radar typically employs the following processing steps:

Reception of the direct signal from the transmitter(s) and from the surveillance region on dedicated low-noise, linear, digital receivers

Digital beamforming to determine the direction of arrival of signals and spatial rejection of strong in-band interference

Adaptive filtering to cancel any unwanted direct signal returns in the surveillance channel(s)

Transmitter-specific signal conditioning

Cross-correlation of the reference channel with the surveillance channels to determine object bistatic range and Doppler

Detection using constant false alarm rate (CFAR) scheme

Association and tracking of object returns in range/Doppler space, known as "line tracking"

Association and fusion of line tracks from each transmitter to form the final estimate of an objects location, heading and speed

These are described in greater detail in the sections below.

Generic passive radar signal processing scheme Receiver system

A passive radar system must detect very small target returns in the presence of very strong, continuous interference. This contrasts with a conventional radar, which listens for echoes during the periods of silence in between each pulse transmission. As a result, it is essential that the receiver should have a low noise figure, high dynamic range and high linearity. Despite this, the received echoes are normally well below the noise floor and the system tends to be externally noise limited (due to reception of the transmitted signal itself, plus reception of other distant in-band transmitters). Passive radar systems use digital receiver systems which output a digitized, sampled signal.

Digital beamforming

Most passive radar systems use simple antenna arrays with several antenna elements and element-level digitisation. This allows the direction of arrival of echoes to be calculated using standard radar beamforming techniques, such as amplitude monopulse using a series of fixed, overlapping beams or more sophisticated adaptive beamforming. Alternatively, some research systems have used only a pair of antenna elements and the phase-difference of arrival to calculate the direction of arrival of the echoes (known as phase interferometry and similar in concept to Very Long Baseline Interferometry used in astronomy).

Signal conditioning

With some transmitter types, it is necessary to perform some transmitter-specific conditioning of the signal before cross-correlation processing. This may include high quality analogue bandpass filtering of the signal, channel equalization to improve the quality of the reference signal, removal of unwanted structures in digital signals to improve the radar ambiguity function or even complete reconstruction of the reference signal from the received digital signal.

Adaptive filtering

The principal limitation in detection range for most passive radar systems is the signal-to-interference ratio, due to the large and constant direct signal received from the transmitter. To remove this, an adaptive filter can be used to remove the direct signal in a process similar to active noise control. This step is essential to ensure that the range/Doppler sidelobes of the direct signal do not mask the smaller echoes in the subsequent cross-correlation stage.

In a few specific cases, the direct interference is not a limiting factor, due to the transmitter being beyond the horizon or obscured by terrain (such as with the Manastash Ridge Radar), but this is the exception rather than the rule, as the transmitter must normally be within line-of-sight of the receiver to ensure good low-level coverage.

Cross-correlation processing

The key processing step in a passive radar is cross-correlation. This step acts as the matched filter and also provides the estimates of the bistatic range and bistatic Doppler shift of each target echo. Most analogue and digital broadcast signals are noise-like in nature, and as a consequence they tend to only correlate with themselves. This presents a problem with moving targets, as the Doppler shift imposed on the echo means that it will not correlate with the direct signal from the transmitter. As a result, the cross-correlation processing must implement a bank of matched filters, each matched to a different target Doppler shift. Efficient implementations of the cross-correlation processing based on the discrete Fourier transform are usually used. The signal processing gain is typically equal to the time-bandwidth product, BT, where B is the waveform bandwidth and T is the length of the signal sequence being integrated. A gain of 50dB is not uncommon. Extended integration times are limited by the motion of the target and its smearing in range and Doppler during the integration period.

Target detection

Targets are detected on the cross-correlation surface by applying an adaptive threshold, and declaring all returns above this surface to be targets. A standard cell-averaging constant false alarm rate (CFAR) algorithm is typically used.

Line tracking

The line-tracking step refers to the tracking of target returns from individual targets, over time, in the range-Doppler space produced by the cross-correlation processing. A standard Kalman filter is typically used. Most false alarms are rejected during this stage of the processing.

Track association and state estimation

In a simple bistatic configuration (one transmitter and one receiver) it is possible to determine the location of the target by simply calculating the point of intersection of the bearing with the bistatic-range ellipse. However, errors in bearing and range tend to make this approach fairly inaccurate. A better approach is to estimate the target state (location, heading and speed) from the full measurement set of bistatic range, bearing and Doppler using a non-linear filter, such as the extended or unscented Kalman filter.

When multiple transmitters are used, a target can be potentially detected by every transmitter. The return from this target will appear at a different bistatic range and Doppler shift with each transmitter and so it is necessary to determine which target returns from one transmitter correspond with those on the other transmitters. Having associated these returns, the point at which the bistatic range ellipses from each transmitter intersect is the location of the target. The target can be located much more accurately in this way, than by relying on the intersection of the (inaccurate) bearing measurement with a single range ellipse. Again the optimum approach is to combine the measurements from each transmitter using a non-linear filter, such as the extended or unscented Kalman filter.

Narrow band and CW illumination sources

The above description assumes that the waveform of the transmitter being exploited possesses a usable radar ambiguity function and hence cross-correlation yields a useful result. Some broadcast signals, such as analogue television, contain a structure in the time domain that yields a highly ambiguous or inaccurate result when cross-correlated. In this case, the processing described above is ineffective. If the signal contains a continuous wave (CW) component, however, such as a strong carrier tone, then it is possible to detect and track targets in an alternative way. Over time, moving targets will impose a changing Doppler shift and direction of arrival on the CW tone that is characteristic of the location, speed and heading of the target. It is therefore possible to use a non-linear estimator to estimate the state the of the target from the time history of the Doppler and bearing measurements. Work has been published that has demonstrated the feasibility of this approach for tracking aircraft using the vision carrier of analogue television signals. However, track initiation is slow and difficult, and so the use of narrow band signals is probably best considered as an adjunct to the use of illuminators with better ambiguity surfaces.

Performance

Passive radar performance is comparable to conventional short and medium range radar systems. Detection range can be determined using the standard radar equation, but ensuring proper account of the processing gain and external noise limitations is taken. Furthermore, unlike conventional radar, detection range is also a function of the deployment geometry, as the distance of the receiver from the transmitter determines the level of external noise against which the targets must be detected. However, as a rule of thumb it is reasonable to expect a passive radar using FM radio stations to achieve detection ranges of up to 150 km, for high-power analogue TV and US HDTV stations to achieve detection ranges of over 300 km and for lower power digital signals (such as cell phone and DAB or DVB-T) to achieve detection ranges of a few tens of kilometers.

Passive radar accuracy is a strong function of the deployment geometry and the number of receivers and transmitters being used. Systems using only one transmitter and one receiver will tend to be much less accurate than conventional surveillance radars, whilst multistatic systems are capable of achieving somewhat greater accuracies. Most passive radars are two-dimensional, but height measurements are possible when the deployment is such there is significant variation in the altitudes of the transmitters, receiver and target, reducing the effects of geometrical dilution of precision (GDOP).

Advantages and disadvantages

Advocates of the technology cite the following advantages:

Lower procurement cost

Lower costs of operation and maintenance, due to the lack of transmitter and moving parts

Covert operation, including no need for frequency allocations

Physically small and hence easily deployed in places where conventional radars cannot be

Capabilities against stealth aircraft due to the frequency bands and multistatic geometries employed

Rapid updates, typically once a second

Difficulty of jamming

Resilience to anti-radiation missiles

Opponents of the technology cite the following disadvantages:

Immaturity

Reliance on third-party illuminators

Complexity of deployment

2D operation

Commercial systems

Passive radar systems are currently under development in several commercial organizations. Of these, the systems that have been publicly announced include:

Lockheed-Martin's Silent Sentry - exploiting FM radio stations

BAE Systems' CELLDAR - exploiting GSM base stations

Thales Air Systems' Homeland Alerter - FM radio based system

Current research

Research on passive radar systems is of growing interest throughout the world, with various open source publications showing active research and development in the United States (including work at the Air Force Research Labs, Lockheed-Martin Mission Systems, Raytheon, University of Washington, Georgia Tech/Georgia Tech Research Institute and the University of Illinois), in the NATO C3 Agency in The Netherlands, in the United Kingdom (at Roke Manor Research, QinetiQ, University of Birmingham, University College London and BAE Systems, France (including the government labs of ONERA), Germany (including the labs at FGAN-FHR), Poland (including Warsaw University of Technology). There is also active research on this technology in several government or university laboratories in China, Iran, Russia and South Africa. The low cost nature of the system makes the technology particularly attractive to university laboratories and other agencies with limited budgets, as the key requirements are less hardware and more algorithmic sophistication and computational power.

Much current research is currently focusing on the exploitation of modern digital broadcast signals. The US HDTV standard is particularly good for passive radar, having an excellent ambiguity function and very high power transmitters. The DVB-T digital TV standard (and related DAB digital audio standard) used throughout most of the rest of the world is more challenging—transmitter powers are lower, and many networks are set up in a "single frequency network" mode, in which all transmitters are synchronised in time and frequency. Without careful processing, the net result for a passive radar is like multiple repeater jammers!

Target imaging

Researchers at the University of Illinois at Urbana-Champaign and Georgia Institute of Technology, with the support of DARPA and NATO C3 Agency, have shown that it is possible to build a synthetic aperture image of an aircraft target using passive multistatic radar. Using multiple transmitters at different frequencies and locations, a dense data set in Fourier space can be built for a given target. Reconstructing the image of the target can be accomplished through an inverse fast Fourier transform (IFFT). Herman, Moulin, Ehrman and Lanterman have published reports based on simulated data, which suggest that low frequency passive radars (using FM radio transmissions) could provide target classification in addition to tracking information. These Automatic Target Recognition systems use the power received to estimate the RCS of the target. The RCS estimate at various aspect angles as the target traverses the multistatic system are compared to a library of RCS models of likely targets in order to determine target classification. In the latest work, Ehrman and Lanterman implemented a coordinated flight model to further refine the RCS estimate.

Ionospheric Turbulence Studies

Researchers at the University of Washington operate a distributed passive radar exploiting FM broadcasts to study ionospheric turbulence at altitudes of 100 km and ranges out to 1200 km. Meyer and Sahr have demonstrated interferometric images of ionospheric turbulence with angular resolution of 0.1 degree, while also resolving the full, unaliased Doppler Power Spectrum of the turbulence.

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