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--- radar:doppler [2018/05/30 00:07] – masrour
+++ radar:doppler [2026/04/28 15:13] (current) – external edit 127.0.0.1
@@ Line 35: / Line 35: @@
 <figure label>
  {{ :media:figure_2.radar.png?500x500 }}
-<caption> Doppler Effect [(cite:image1>> title: https://www.texasgateway.org ,section:Wave behaviour:the doppler effect ,publisher:Texas Education Agency 1701 ,published:2007
+<caption> Doppler Effect [(cite:image1>>title: https://www.texasgateway.org ,section:Wave behaviour:the doppler effect ,publisher:Texas Education Agency 1701 ,published:2007
 )] </caption>
 </figure>
@@ Line 164: / Line 164: @@
 The phases of the transmitted signal are random from pulse to pulse. The phases of the echoes cannot be used to predict the range of the target.
-One of the transmitting systems is the __**POT**__ (**P**ower **O**scillator **T**ransmitter) which is self-oscillating. When such a device is switched ON and OFF as a result of modulation by the rectangular modulating pulse, the starting phase of each pulse is not the same for the different successive pulses. The starting phase is a random function related to the startup process of the oscillator.
+Another kind of the transmitting systems is the __**POT**__ (**P**ower **O**scillator **T**ransmitter) which is self-oscillating. When such a device is switched ON and OFF as a result of modulation by the rectangular modulating pulse, the starting phase of each pulse is not the same for the different successive pulses. The starting phase is a random function related to the startup process of the oscillator.
     * Notice: Self-oscillating transmitter gives random phase pulse to pulse and is not coherent!
@@ Line 247: / Line 247: @@
 <figure label>
 {{ :media:new_cw.png?400x400 }}
-<caption> (upper . Fig) Simple CW radar block diagram ; (lower. Fig) response characteristic of beat-frequency amplifier [(cite:Image8>> title: http://nptel.ac.in/courses/101108056/module2/lecture4.pdf,section:Cw Radar:Doppler frequency shift,publisher:nptel
+<caption> (upper . Fig) Simple CW radar block diagram ; (lower. Fig) response characteristic of beat-frequency amplifier [(cite:Image8>> title: http://nptel.ac.in/courses/101108056/module2/lecture4.pdf ,section:Cw-Radar,Doppler frequency shift,publisher:nptel)] </caption>
-)] </caption>
 </figure>
@@ Line 282: / Line 281: @@
    * Doppler frequency usually falls in the audio or video frequency range which is more susceptible to flicker noise.
    * Flicker noise is inversely proportional to frequency. So as we shift the Doppler frequency to IF flicker noise reduces.
-   * Super-heterodyne receiver with non zero IF increases the receiver sensitivity above **$30$* dB
+   * Super-heterodyne receiver with non zero IF increases the receiver sensitivity above **$30$** dB
 **Receiver bandwidth** :
@@ Line 288: / Line 287: @@
    * IF amplifier should be wide enough to pass the expected range of Doppler frequencies.
    *Usually expected the range of Doppler frequencies will be much higher than the Doppler frequency. So a wideband amplifier is needed.
-   * But as a Receiver bandwidth in increased noise, increases and sensitivity degrades.
+   * But as a Receiver bandwidth in increased noise, increases and sensitivity degrade.
    * And also the Transmitted signal bandwidth is not narrow.
    * So Received signal bandwidth again increases.
@@ Line 322: / Line 321: @@
-In some application of CW radar, it is of interest to know whether the target is approaching or receding. This might be determined with separate filters located on either side of the intermediate frequency. If echo-signal frequency lies below the carrier, the target is receding; if the echo frequency is greater than the carrier, the target is approaching $ Fig.14$.
+In some application of CW radar, it is of interest to know whether the target is approaching or receding. This might be determined with separate filters located on either side of the intermediate frequency. If echo-signal frequency lies below the carrier, the target is receding; if the echo frequency is greater than the carrier, the target is approaching $ Fig.12$.
 The sign of Doppler angular frequency shift ** $ω_d$ ** and the direction of the target's motion may be determined according to whether the output of channel $B$ leads or legs the output of channel $A$.
@@ Line 331: / Line 330: @@
 <figure label>
 {{ :media:sign_detector.png }}
-<caption>Measurement of doppler direction using synchronous ,two-phase motor.[(#13)]</caption>
+<caption>Measurement of doppler direction using synchronous ,two-phase motor.[(cite:Image9)]</caption>
 </figure>
-If the output of channel B leads to the output of channel A, the Doppler shift is Positive //Approaching Target//.
-If the output of channel B leads to the output of channel A, the Doppler shift is Negative //Receding Target//.
+If the output of channel B leads to the output of channel A, the Doppler shift is (Positive) Approaching Target.
+If the output of channel B leads to the output of channel A, the Doppler shift is (Negative) Receding Target.
 \begin{equation}
@@ Line 351: / Line 352: @@
   * $ω_0$ = angular frequency of transmitter [rad/s]
   * $Φ$ = a constant phase shift, which depends upon range of initial detection
-**Applications of CW radar with Non-zero IF**:
-  * Police speed monitor
-  * Rate-of-climb meter (During aircraft take off)
-  * Vehicle counting
-  * As a replacement for “5th wheel speedometer” in-vehicle testing
-  * Antilock braking system
-  * Collision avoidance
-  * In railways as speedometer instead of a tachometer
-  * Advance warning system for approaching targets
-  * Docking speed measurement of large ships
-  * Intruder alarms
-  * Measurement of the velocity of missiles, baseball etc
-**Limitations of CW radar with Non-zero IF**:
-  * False targets
-  * Unable to detect the range of the target
 **Frequency Modulated CW radar**
-**FMCW** radar is capable to measure the relative velocity and the range of the target with the expense of bandwidth. An example of an amplitude modulation frequency is the pulse radar.
+**FMCW** radar is capable to measure the relative velocity and the range of the target with the expense of bandwidth. An example of an amplitude modulation frequency is the **pulse radar**.
-By providing timing marks into the Transmitted signal the time of transmission and the time of return can be calculated. This will increase the bandwidth. More distinct the timing, more accurate the result will be and broader will the Transmitted spectrum. Here it is done by frequency modulating the carrier and the timing mark is the change in frequency.
+By providing //$timing$ $marks$// into the Transmitted signal the time of transmission and the time of return can be calculated. This will increase the bandwidth. More distinct the timing, more accurate the result will be and broader will the Transmitted spectrum. Here it is done by frequency modulating the carrier and the timing mark is the change in frequency.
  <figure label>
 {{ :media:fm-cw.png }}
-<caption>Block diagram of FM-CW radar.[(#13)]</caption>
+<caption>Block diagram of FM-CW radar.[(cite:Image9)]</caption>
 </figure>
 Transmitted frequency increases linearly with time (solid line).Solid curve represents transmitted signal;Dashed curve represents echo.
@@ Line 385: / Line 367: @@
  <figure label>
 {{ :media:solid_ang.png }}
-<caption>Frequency-relationships in FM-CW radar.($a$)Linear frequency modulation. [(#13)]</caption>
+<caption>Frequency-relationships in FM-CW radar.($a$)Linear frequency modulation. [(cite:Image9)]</caption>
 </figure>
-The echo signal will return after a time $T = 2R/c$ (dashed line).
+The echo signal will return after a time $T = \frac{2R}{c}$ (dashed line).
-If the echo signal is heterodyned with a portion of the transmitter signal in a nonlinear element such as a diode, a beat note $f_b$ will be produced. If there is no Doppler frequency shift, the beat note is a measure of the target's range and $f_b = f_r$, If the rate of change of the carrier frequency is $f_0 $, the beat frequency is :
+If the echo signal is heterodyned with a portion of the transmitter signal in a nonlinear element such as a diode, a beat note $f_b$ will be produced. If there is no **Doppler frequency shift**, the beat note is a measure of the target's range and $f_b = f_r$, If the rate of change of the carrier frequency is $f_0 $, the beat frequency is :
 \begin{equation}
 f_r = {f_0}T = \frac{2R}{c} f_0
@@ Line 397: / Line 379: @@
 <figure label>
 {{ :media:rect_modul.png?300x50 }}
-<caption>($b$) Triangular frequency modulation; ($c$) Beat note of $b$ [(#13)]</caption>
+<caption>($b$) Triangular frequency modulation; ($c$) Beat note of $b$ [(cite:Image9)]</caption>
 </figure>
@@ Line 409: / Line 391: @@
-The reference signal from the transmitter is used to produce the beat frequency note. The beat frequency is amplified and limited to eliminate any amplitude fluctuations. The frequency of the amplitude-limited beat note is measured with a cycle counting frequency meter calibrated in distance, If the target is not stationary Doppler frequency shift will be superimposed on the $FM$ range beat note and an erroneous range measurement results
+The reference signal from the transmitter is used to produce the beat frequency note. The beat frequency is amplified and limited to eliminate any amplitude fluctuations. The frequency of the amplitude-limited beat note is measured with a cycle counting frequency meter calibrated in distance, If the target is not stationary Doppler frequency shift will be superimposed on the FM range beat note and a wrong range measurement results
 <figure label>
 {{ :media:fmcw-time.png?350x50 }}
-<caption>Frequency-time relationships in FM-CW radar when the received signal is shifted in frequency by the doppler effect. (a) Transmitted(solid curve) and echo(dashed curve)frequencies;(b)Beat frequency.[(#13)]</caption>
+<caption>Frequency-time relationships in FM-CW radar when the received signal is shifted in frequency by the doppler effect. (a) Transmitted (solid curve) and echo(dashed curve) frequencies;(b) Beat frequency.[(cite:Image9)]</caption>
 </figure>
@@ Line 426: / Line 408: @@
 \end{equation}
-One-half the difference between the frequencies will yield the Doppler frequency. If there is more than one target, the range to each target may be measured by measuring the individual frequency components by using a bank of narrowband filters. If the targets are moving the task of measuring the range of each becomes complicated.
+One-half the difference between the frequencies will yield the Doppler frequency. If there is "more than one target" the range to each target may be measured by measuring the individual frequency components by using a bank of narrowband filters. If the targets are moving the task of measuring the range of each becomes complicated.
 **FM CW Altimeter**
 To measure the height above the surface of the earth FM-CW radar is used as aircraft radio altimeter. Low Transmitted power and low antenna gain are needed because of short range. Since the relative motion between the aircraft and ground is small, the effect of the Doppler frequency shift may usually be neglected.
-Frequency range: $4.2$ to $4.4$ Ghz (reserved for altimeters).
+And the frequency range is $4.2$ to $4.4$ Ghz (reserved for altimeters).
-Solid state Transmitted is used here.
+Solid state Transmitted is used here. In general
-High sensitive super-heterodyne Rx is preferred for better sensitivity and stability
+high sensitive super-heterodyne Receiver is preferred for better sensitivity and stability.
 <figure label>
 {{ :media:fm-cw_side_band.png?400x100 }}
-<caption> Block diagram of FM-CW radar using side band superheterodyne receiver.[(#13)]</caption>
+<caption> Block diagram of FM-CW radar using side band superheterodyne receiver.[(cite:Image9)]</caption>
 </figure>
 The output of the detector contains the beat frequency which contains doppler frequency and the range frequency. It is amplified to a level enough to actuate the frequency measuring circuits.
@@ Line 448: / Line 434: @@
 and The switched frequency counter determines the Doppler velocity. The averaging frequency counter is necessary for an altimeter since the rate of change of altitude is usually small.
-In an altimeter, the echo signal from an extended target varies inversely as the square (rather than the $4th$ power) of the range, because of greater the range greater the echo area illuminated by the beam.
+In an altimeter, the echo signal from an extended target varies inversely as the square (rather than the $4$th power) of the range, because of greater the range greater the echo area illuminated by the beam.
 The low-frequency amplifier is a narrow band filter which is wide enough to pass the received signal energy, thus reducing the amount of noise with which the signal must compete.
 The average frequency counter is a cycle counter. It counts only absolute numbers. So there may be step errors or quantization errors.
 **Unwanted signals in FM altimeter**:
-  *  The reflection of the transmitted signals at the antenna caused by impedance mismatch.
+  -  The reflection of the transmitted signals at the antenna caused by impedance mismatch.
-  *  The standing-wave pattern on the cable feeding the reference signal to the receiver, due to poor mixer match.
+  -  The standing-wave pattern on the cable feeding the reference signal to the receiver, due to poor mixer match.
-  *  The leakage signal entering the receiver via coupling between transmitter and receiver antennas. This can limit the ultimate receiver sensitivity, especially at high altitudes.
+  -  The leakage signal entering the receiver via coupling between transmitter and receiver antennas. This can limit the ultimate receiver sensitivity, especially at high altitudes.
-  *  The interference due to power being reflected back to the transmitter, causing a change in the impedance seen by the transmitter. This is usually important only at low altitudes. It can be reduced by an attenuator introduced in the transmission line at low altitude or by a directional coupler or an isolator.
+  -  The interference due to power being reflected back to the transmitter, causing a change in the impedance seen by the transmitter. This is usually important only at low altitudes. It can be reduced by an attenuator introduced in the transmission line at low altitude or by a directional coupler or an isolator.
-  *  The double-bounce signal.
+  -  The double-bounce signal.
@@ Line 463: / Line 449: @@
 <figure label>
 {{ :media:unwanted_signal_in_fm_altimeter.png?300x50 }}
-<caption> Unwanted signals in FM altimeter.[(#13)]</caption>
+<caption> Unwanted signals in FM altimeter.[(cite:Image9)]</caption>
 </figure>
@@ Line 480: / Line 466: @@
 <figure label>
 {{ :media:simpcw.png?400 }}
-<caption>($a$) Simple CW radar; ($b$) Pulse radar using doppler information.[(#13)] </caption>
+<caption>($a$) Simple CW radar; ($b$) Pulse radar using doppler information.[(cite:Image9)] </caption>
 </figure>
-The difference between simple pulse radar and pulse Doppler radar is that in pulse Doppler radar the reference signal at the receiver is derived from the transmitter, whereas in simple pulse radar the reference signal at the receiver is from a local oscillator.
+The difference between simple pulse radar and pulse Doppler radar is that in pulse Doppler radar the reference signal at the receiver is derived from the transmitter, but in simple pulse radar, the reference signal at the receiver is from a local oscillator.
 Here the reference signal acts as the coherent reference needed to detect the Doppler frequency shift. The phase of the transmitted signal is preserved in the reference signal.
 Operation:
@@ Line 523: / Line 509: @@
 <figure label>
 {{ :media:mti2.png?400x50 }}
-<caption>Pulse radar for CW oscillator voltage[(#13)] </caption>
+<caption>Pulse radar for CW oscillator voltage[(cite:Image9)] </caption>
 </figure>
-Sample waveforms (//bipolar//)
+Sample waveforms (**bipolar**)
 <figure label>
 {{ :media:mti3.png?300 }}
-<caption> The video signal waveforms "Bipolar", since they contain both positive and negative amplitude.[(#13)]</caption>
+<caption> The video signal waveforms "Bipolar", since they contain both positive and negative amplitude.[(cite:Image9)]</caption>
 </figure>
@@ Line 537: / Line 523: @@
-Moving targets may be distinguished from stationary targets by observing the video output on an A-scope (amplitude vs. range).
+Moving targets may be distinguished from stationary targets by observing the video output on an A-scope (**amplitude** vs. **range**).
 Echoes from fixed targets remain constant throughout, but echoes from moving targets vary in amplitude from sweep to sweep at a rate corresponding to the Doppler frequency.
-The superposition of the successive A-scope sweeps is shown in $Fig.25$ [$b$ to $e$] The moving targets produce, with time, a " butterfly" effect on the A-scope.
+The superposition of the successive A-scope sweeps is shown in $Fig.23$ [$b$ to $e$] The moving targets produce, with time, a  “butterfly” effect on the A-scope.
 It is not appropriate for display on the PPI.
 <figure label>
 {{ :media:a-scope.png?200 }}
-<caption>($a-e$) Figure succesive sweeps of an MTI radar A-scope display(echo amplitude as a function of time); ($f$) superposition of many sweeps; arrows indicate position of moving targets.[(#13)]</caption>
+<caption>($a-e$) Figure succesive sweeps of an MTI radar A-scope display(echo amplitude as a function of time) ; ($f$) superposition of many sweeps; arrows indicate position of moving targets.[(cite:Image9)]</caption>
 </figure>
@@ Line 553: / Line 539: @@
 <figure label>
 {{ :media:mti_receiver_canceler.png?500x50 }}
-<caption>MTI receiver with delta-line canceler.[(#13)]</caption>
+<caption>MTI receiver with delay-line canceler.[(cite:Image9)]</caption>
 </figure>
-The delay-line canceler acts as a filter to eliminate the dc component of fixed targets and to pass the ac components of moving targets.
+The delay-line canceler acts as a filter to eliminate the DC component of fixed targets and to pass the AC components of moving targets.
@@ Line 564: / Line 550: @@
 <figure label>
 {{ :media:typical_mti.png?300 }}
-<caption>Block diagram of MTI radar with power amplifier transmitter.[(#13)]</caption>
+<caption>Block diagram of MTI radar with power amplifier transmitter.[(cite:Image9)]</caption>
 </figure>
@@ Line 573: / Line 559: @@
 The local oscillator must also be a **sta**ble oscillator and is called **Sta**lo, for the stable local oscillator. The RF echo signal is heterodyned with the Stalo signal to produce the IF signal just as in the conventional super-heterodyne receiver.
-The characteristic feature of coherent MTI radar is that the transmitted signal must be coherent (in phase) with the reference signal in the receiver. This is accomplished by the coho signal. The function of the Stalo is to provide the necessary frequency translation from the IF to the transmitted (RF) frequency. Any Stalo phase shift is canceled on reception.
+The characteristic feature of coherent MTI radar is that the transmitted signal must be coherent (in phase) with the reference signal in the receiver. This is accomplished by the coho signal. The function of the Stalo is to provide the necessary frequency translation from the IF to the transmitted RF frequency. Any Stalo phase shift is canceled on reception.
-The reference signal from the coho and the IF echo signal are both fed into a mixer called the phase detector. Its output is proportional to the phase difference between the two input signals.
+The reference signal from the coho and the IF echo signal are both fed into a **mixer** called the **phase detector**. Its output is proportional to the phase difference between the two input signals.
 Triode, Tetrode, Klystron, Traveling-wave tube, and the Crossed-field amplifier can be used as the power amplifier.
-A transmitter which consists of a stable low- power oscillator followed by a power amplifier is sometimes called MOPA, which stands for master- oscillator power amplifier.
+A transmitter which consists of a stable low- power oscillator followed by a power amplifier is sometimes called **MOPA**, which stands for master- oscillator power amplifier.
@@ Line 585: / Line 571: @@
 **MTI radar (with power-oscillator Transmitter)**
-In an oscillator, the phase of the RF bears no relationship from pulse to pulse. For this reason, the reference signal cannot be generated by a continuously running oscillator. However, a coherent reference signal may be readily obtained with the power oscillator by **readjusting the phase of the coho at the beginning of each sweep according to the phase of the transmitted pulse**. The phase of the coho is locked to the phase of the transmitted pulse each time a pulse is generated.
+In an oscillator, the phase of the RF bears no relationship from pulse to pulse. For this reason, the reference signal cannot be generated by a continuously running oscillator. However, a coherent reference signal may be readily obtained with the power oscillator by remodifying the phase of the coho at the beginning of each sweep according to the phase of the transmitted pulse. The phase of the coho is locked to the phase of the transmitted pulse each time a pulse is generated.
  <figure label>
 {{ :media:new.png?450x50 }}
-<caption>Block diagram of MTI radar with power amplifier transmitter[(#13)]</caption>
+<caption>Block diagram of MTI radar with power amplifier transmitter[(cite:Image9)]</caption>
  </figure>
-A portion of the transmitted signal is mixed with the Stalo output to produce an IF beat signal whose phase is directly related to the phase of the transmitter.
+A portion of the transmitted signal is mixed with the Stalo output to produce an **IF beat signal** whose phase is directly related to the phase of the transmitter.
 This IF pulse is applied to the coho and causes the phase of the coho CW oscillation to "lock" in step with the phase of the IF reference pulse.
@@ Line 601: / Line 587: @@
 **Delay Lines and cancelers**
-The simple delay-line canceler is limited in its ability to do all that might be desired of an MTI filter.
+The **simple delay-line canceler** is limited in its ability to do all that might be desired of an MTI filter.
 The delay line must introduce a delay equal to the pulse-repetition interval.
 One of the advantages of a time-domain delay-line canceler, as compared to the more conventional frequency-domain filter, is that a single network operates at all ranges and does not require a separate filter for each range resolution cell. Frequency-domain doppler filter- banks are of interest in some forms of MTI and pulse-doppler radar.
@@ Line 608: / Line 594: @@
 **Filter characteristics of the delay-line canceler**
-The delay-line canceler acts as a filter which rejects the d-c component of clutter. Because of its periodic nature, the filter also rejects energy in the vicinity of the pulse repetition frequency and its harmonics. the video signal  [$Eq.13$] received from a target at a range $R_0$ is
+The delay-line canceler acts as a filter which rejects the DC component of clutter. Because of its periodic nature, the filter also rejects energy in the vicinity of the pulse repetition frequency and its harmonics. the video signal  ($Eq.13$) received from a target at a range $R_0$ is
 \begin{equation}
@@ Line 627: / Line 613: @@
 \end{equation}
-It is assumed that the gain through the delay-line canceler is unity. The output from the canceler [$Eq.16$] consists of a cosine wave at the Doppler frequency $f_d$ with an amplitude $k.sin \pi{f_d}T$: Thus the amplitude of the canceled video output is a function of the Doppler frequency shift and the pulse-repetition interval or PRF
+It is assumed that the gain through the delay-line canceler is unity. The output from the canceler ($Eq.16$) consists of a cosine wave at the Doppler frequency $f_d$ with an amplitude ($k.sin \pi{f_d}T$):  Thus the amplitude of the canceled video output is a function of the Doppler frequency shift and the pulse-repetition interval or PRF. the ordinate sometimes called the  $visibility$ $factor$.
 <figure label>
 {{ :media:delay_line_c.png?400 }}
-<caption>Frequency response of the single delay-line canceler; $T$= delay time    = $1/f_r$.
+<caption>Frequency response of the single delay-line canceler; $T$= delay time = $1/f_r$
-[(#13)]</caption>
+[(cite:Image9)]</caption>
  </figure>
@@ Line 649: / Line 639: @@
 \end{equation}
-where $n$ = $0, 1, 2, ..$, and $f_r$ = pulse repetition frequency. The delay-line canceler, not only eliminates the d-c component caused by clutter ($n = 0$), it also rejects any moving target whose doppler frequency happens to be the same as the prf or a multiple thereof. Those relative target velocities which result in zero MTI response are called blind speeds are given by
+where $n$ = $0, 1, 2, ..$,  and $f_r$ = pulse repetition frequency. The delay-line canceler, not only eliminates the DC component caused by clutter ($n = 0$), it also rejects any moving target whose doppler frequency happens to be the same as the PRF or a multiple thereof. Those relative target velocities which result in zero MTI response are called blind speeds are given by
 \begin{equation}
@@ Line 656: / Line 646: @@
 where     $n = 1,2,3,.$
-and $v_n$ is the nth blind speed. If $λ$ is measured in [m], $f_r$ in [Hz], and the relative velocity in knots, the blind speeds are
+  and $v_n$ is the nth blind speed. If $λ$ is measured in [m], $f_r$ in [Hz], and the relative velocity in [knots], the blind speeds are
@@ Line 680: / Line 670: @@
-The frequency response of a single-delay-line canceler $Fig.29$ does not always have as broad a clutter-rejection null as might be desired in the vicinity of D-C which limits their rejection of clutter and clutter does not have a zero width spectrum, Adding more cancellers sharpens the nulls.
+The frequency response of a single-delay-line canceler $Fig.27$ does not always have as broad a clutter-rejection null as might be desired in the vicinity of D-C which limits their rejection of clutter and clutter does not have a zero width spectrum, Adding more cancellers sharpens the nulls.
-The two-delay-line configuration of the next $Fig$ has the same frequency-response characteristic as the double-delay-line canceler. The operation of the device is as follows. A signal $f(t)$ is inserted into the adder along with the signal from the preceding pulse period, with its amplitude weighted by the factor - 2, plus the signal from two pulse periods previous. The output of the adder is therefore
+The two-delay-line configuration of $Fig.28b$ has the same frequency-response characteristic as the double-delay-line canceler. The operation of the device is as follows. A signal $f(t)$ is inserted into the adder along with the signal from the preceding pulse period, with its amplitude weighted by the factor - 2, plus the signal from two pulse periods previous. The output of the adder is therefore
 \begin{equation}
@@ Line 691: / Line 681: @@
 <figure label>
 {{ :media:double_delay_line_canc.png?500 }}
-<caption>($a$) Double-delay-iine canceler; ($b$) three-pulse canceler.[(#13)]</caption>
+<caption>($a$) Double-delay-line canceler; ($b$) three-pulse canceler.[(cite:Image9)]</caption>
 </figure>
 These have the same frequency response: which is the square of the single canceller response
@@ Line 702: / Line 694: @@
 <figure label>
 {{ :media:solid_curve_delay_line_canc.png?500 }}
-<caption>Relative frequency response of the single-delay-line canceler (solid curve) and the double- delay-line canceler (dashed curve). Shaded area represents clutter spectrum.[(#13)]</caption>
+<caption>Relative frequency response of the single-delay-line canceler (solid curve) and the double- delay-line canceler (dashed curve). Shaded area represents clutter spectrum.[(cite:Image9)]</caption>
 </figure>
@@ Line 709: / Line 705: @@
 **Transversal filter**
-These are basically a tapped delay line, It is also sometimes known as a feed forward-filter, a non-recursive filter, a finite-memory filter. The weights $w_i$ for a three-pulse canceler utilizing two delay lines arranged as a transversal filter are $1, -2, 1$.
+These are basically a tapped **delay line**, It is also sometimes known as a [feed forward-filter, a non-recursive filter, a finite-memory filter].
-The,frequency response function is proportional to $sin^2 π f_d T$, three delay lines whose weights are $1, -3, 3, -1$ gives a $sin^3 π f_d T$ response. This is a four-pulse canceler.
+The weights $w_i$ for a three-pulse canceler utilizing two delay lines arranged as a transversal filter are $ 1, -2, 1 $.
+The frequency response function is proportional to $sin^2 π f_d T$, three delay lines whose weights are $ 1, -3, 3, -1 $ gives a $sin^3 π f_d T$ response. This is a four-pulse canceler.
   * Note the potentially confusing nomenclature. A cascade configuration of three delay lines, each connected as a single canceler, is called a triple canceler but **when connected as a transversal filter it is called a four-pulse canceler**.
@@ Line 724: / Line 722: @@
 <figure label>
 {{ :media:trasversal.png?350 }}
-<caption>General form of a transversal (or nonrecursive) filter for MTI signal processing.[(#13)]</caption>
+<caption>General form of a transversal (or nonrecursive) filter for MTI signal processing.[(cite:Image9)]</caption>
 </figure>
@@ Line 741: / Line 741: @@
 \end{equation}
-where $(S/C)_{out}$ is the signal-to-clutter ratio at the output of the filter, and $(S/C)_{in}$ is the signal-to-clutter ratio at the input.
+where $(S/C)_{out}$ is the signal-to-clutter ratio at the **output** of the filter, and $(S/C)_{in}$ is the signal-to-clutter ratio at the **input**.
-The ideal MTI filter should be shaped to reject the clutter at d-c and around the prf and its harmonics, but have a flat response over the region where no clutter is expected. That is, it would be desirable to have the freedom to shape the filter response, just as with any conventional filter. The ability to shape the frequency response depends to a large degree on the number of pulses used. The more pulses, the more flexibility in the filter design.
+Which can be expressed as
+\begin{equation}
+I _C = \frac{(S)_{out}}{(S)_{in}}\times CA=(CA)\times G_{N}
+\end{equation}
+where $CA$ is the clutter attenuation and $G_N$ is called Noise Gain.
+The ideal MTI filter should be shaped to reject the clutter at D-C and around the PRF and its harmonics, but have a flat response over the region where no clutter is expected. That is, it would be desirable to have the freedom to shape the filter response, just as with any conventional filter. The ability to shape the frequency response depends to a large degree on the number of pulses used. The more pulses, the more flexibility in the filter design.
 Unfortunately, the number of pulses is limited by the scan rate and the antenna beam width.
@@ Line 750: / Line 760: @@
-The figure shows the amplitude response for ($1$) a classical three-pulse canceler with $ sin^2 π f_d T $ response, ($2$) a five-pulse "optimum " canceler designed to maximize the improvement factor $3$ and ($3$) a 15-pulse canceler with a Chebyshev filter characteristic. The amplitude is normalized by dividing the output of each tap by the square root of
+$Fig.31$ shows the amplitude response for ($1$) a classical three-pulse canceler with $ sin^2 π f_d T $ response, ($2$) a five-pulse "optimum " canceler designed to maximize the improvement factor $3$ and ($3$) a 15-pulse canceler with a __Chebyshev filter__ characteristic. The amplitude is normalized by dividing the output of each tap by the square root of
  $\sum_{i=1}^{N} w_i^{2}$
@@ Line 760: / Line 770: @@
 <figure label>
 {{ :media:w_i.png?400 }}
-<caption>Amplitude responses for three MTI delay-line cancelers.[(#13)] </caption>
+<caption>Amplitude responses for three MTI delay-line cancelers.[(cite:Image9)] </caption>
  </figure>
@@ Line 766: / Line 776: @@
 Non-recursive filters employ only feedforward loops.
-Feedforward (finite impulse response or FIR) filters have only poles (one per delay).
+Feedforward (finite impulse response or **FIR**) filters have only poles (one per delay).
 More flexibility in filter design can be obtained if we use recursive or feedback filters ( also known as infinite impulse response or IIR filters )
@@ Line 775: / Line 785: @@
 <figure label>
 {{ :media:canoni_comb_filt.png?500 }}
-<caption>Canonical-configuration comb filter.[(#13)]</caption>
+<caption>Canonical-configuration comb filter.[(cite:Image9)]</caption>
  </figure>
@@ Line 790: / Line 800: @@
+**Multiple and staggered PRFs**
 An alternative is to use multiple PRFs because the blind speeds (and hence the shape of the filter response) depends on the PRF and, combining two or more PRFs offers an opportunity to shape the overall response.
@@ Line 798: / Line 808: @@
 <figure label>
 {{ :media:t1_t2.png?330 }}
-<caption> ($a$) Frequency-response of a single-delay-line canceler for $f_p$ = $1/T_1$; ($b$) same for $f_p$ = $1/T_2$; c) composite response with $T_1/T_2$ = 4/5.[(#13)]</caption>
+<caption> ($a$) Frequency-response of a single-delay-line canceler for $f_p$ = $1/T_1$; ($b$) same for $f_p$ = $1/T_2$; c) composite response with $T_1/T_2$ = $\frac{4}{5}$ [(cite:Image9)]</caption>
  </figure>
 The closer the ratio $T_1$: $T_2$ approaches unity, the greater will be the value of the first blind speed. However, the first null in the vicinity of $f_d$ = $1 /T_1$ becomes deeper. Thus the choice of  $T_1/T_2$ is a compromise between the value of the first blind speed and the depth of the nulls within the filter passband. The depth of the nulls can be reduced and the first blind speed increased by operating with more than two interpulse periods.
-$Fig.36$ shows the response of a five-pulse stagger (four periods) that might be used with a long-range air traffic control radar.' In this example, the periods are in the ratio $ 25: 30: 27: 31$ and the first blind speed is $28.25$ times that of a constant PRF waveform with the same average period.
+$Fig.34$ shows the response of a five-pulse stagger (four periods) that might be used with a long-range air traffic control radar. In this example, the periods are in the ratio $ 25: 30: 27: 31$ and the first blind speed is $28.25$ times that of a constant PRF waveform with the same average period.
 <figure label>
 {{ :media:limitation_mti.png?400 }}
-<caption> Frequency response of a five-pulse (four-period)stagger.[(#13)]</caption>
+<caption> Frequency response of a five-pulse (four-period)stagger.[(cite:Image9)]</caption>
  </figure>
@@ Line 822: / Line 834: @@
 <figure label>
 {{ :media:prf_constante.png?330 }}
-<caption> Response of a weighted five-pulse canceler. Dashed curve, constant prf; solid curve, staggered prf's.[(#13)]</caption>
+<caption> Response of a weighted five-pulse canceler. (Dashed curve) constant prf; (solid curve) staggered prf's [(cite:Image9)]</caption>
  </figure>
-**Digital Signal Processing**
+**Digital (Discrete) Signal Processing**
 The convenience of digital means that multiple delay-line cancellers with tailored frequency-response characteristics can be readily achieved. And Most of the advantages of a digital MTI processor are due to its use of digital delay lines.
@@ Line 835: / Line 847: @@
 <figure label>
 {{ :media:dsp_mti.png?500 }}
-<caption> Block diagram of a simple digital MTI signal processor.[(#13)]</caption>
+<caption> Block diagram of a simple digital MTI signal processor.[(cite:Image9)]</caption>
  </figure>
-  * Note: The quadrature channel removes blind phases and the requirements for the A/D are not very difficult to meet with today’s technology.
+  * Note: The **quadrature channel** removes blind phases and the requirements for the A/D are not very difficult to meet with today’s technology.
-Sampling Rate :
+__Sampling Rate__ :
-Assuming a resolution ($R_{res}$) of $150$ m, the received signal has to be sampled at intervals of $c/2R_{res}$ = $1$μs or a sampling rate of $1$ Mhz
+Assuming a resolution ($R_{res}$) of $150$m, the received signal has to be sampled at intervals of $2R_{res}/c$ = $1$μs or a sampling rate of $1$ MHz
-Memory Requirement :
+__Memory Requirement__ :
 Assuming an antenna rotation period of $12$ s ($5$rpm) the storage required would be only $12$ Mbytes/scan.
-Quantization Noise :
+__Quantization Noise__ :
 The A/D introduces noise because it quantizes the signal.
-The **Improvement Factor** can be limited by the quantization noise the limit being:
+The **Improvement Factor** on the average,can be limited by the quantization noise .the limit being:
@@ Line 861: / Line 873: @@
 In practice one or more extra bits to achieve the desired performance.
-Dynamic Range:
+__Dynamic Range__:
-This is the maximum signal to noise ratio that can be handled by the A/D without saturation
+the maximum signal to noise ratio that can be handled by the A/D without saturation and
  Dynamic _ Range = $2^{2N-3} /k^2 $
@@ Line 868: / Line 880: @@
   * $N$ = number of bits
-  * $k$ = RMS noise level divided by the quantization interval (the larger k the lower the dynamic range but $k$<$1$ results in the reduction of sensitivity )
+  * $k$ = RMS noise level divided by the quantization interval (the larger k the lower the dynamic range but $k<1$ results in the reduction of sensitivity )
-   * Note: A $10$ bit A/D gives a dynamic range of $45.2$ dB.
+   * Note: A $10$-bit A/D gives a dynamic range of $45.2$ dB.
-**Blind speed in an MTI radar**
+**Blind speed in a MTI radar**
 If the PRF is double the Doppler frequency then every other pair of samples can be the same amplitude thus it will be filtered out of the signal.
-By using both in-phase and quadrature signals, blind phases can be eliminated.
+By using both **I**n-phase and **Q**uadrature signals, blind phases can be eliminated.
 <figure label>
 {{ :media:blind_phases2.png?300 }}
-<caption>Blind speed in an MTI radar, The target doppler frequency is equal to the prf. ($b$) Effect of blind phase in the **I** channel, and ($c$) in the **Q** channel [(#13)]</caption>
+<caption>Blind speed in an MTI radar, The target doppler frequency is equal to the prf. ($b$) Effect of blind phase in the **I** channel, and ($c$) in the **Q** channel [(cite:Image9)]</caption>
  </figure>
@@ Line 892: / Line 904: @@
 **Digital filter banks and the FFT**
-A transversal filter with N outputs (N pulses and N - 1 delay lines) can be made to form a bank of N contiguous filters covering the frequency range from $0$ to $f_p$.
+A transversal filter with N outputs (N pulses and N-1 delay lines) can be made to form a bank of N contiguous filters covering the frequency range from $0$ to $f_p$.
-Consider the transversal filter that was shown in $Fig.32$ to have N - 1 delay lines each with a delay time $T$ = $1/f_p $ . Let the weights applied to the outputs of the N taps be:
+Consider the transversal filter that was shown in $Fig.30$ to have N - 1 delay lines each with a delay time $T$ = $1/f_p $ . Let the weights applied to the outputs of the N taps be:
@@ Line 926: / Line 938: @@
 <figure label>
 {{ :media:dsp_respo.png?400 }}
-<caption>MTI doppler filter bank resulting from the processing of N = $8$ pulses [(#13)]</caption>
+<caption>MTI doppler filter bank resulting from the processing of N = $8$ pulses [(cite:Image9)]</caption>
  </figure>
-For comparison, the improvement factor for an N-pulse canceller is shown in the next $Fig$.
+For comparison, the improvement factor for an N-pulse canceller is shown in $Fig.40$.
   * Note that the improvement factor of a two-pulse canceler is almost as good as that of the $8$-pulse doppler-filter bank. The three-pulse canceler is even better. ( Maximizing the average improvement factor might not be the only criterion used in judging the effectiveness of MTI doppler processors.)
@@ Line 935: / Line 947: @@
 <figure label>
 {{ :media:filter_b.png?400 }}
-<caption>Improvement factor for each filter of an $8$-pulse doppler filter bank with uniform weighting as a function of the clutter spectral width (standard deviation). The average improvement for all filters is indicated by the dotted curve.[(#13)]</caption>
+<caption>Improvement factor for each filter of an $8$-pulse doppler filter bank with uniform weighting as a function of the clutter spectral width (standard deviation). The average improvement for all filters is indicated by the dotted curve.[(cite:Image9)]</caption>
  </figure>
@@ Line 942: / Line 954: @@
 <figure label>
 {{ :media:npulse_filtro.png?400 }}
-<caption> Improvement factor for an N-pulse delay-line canceler with optimum weights (solid curves) and binomial weights (dashed curves), as a function of the clutter spectral width.[(#13)]</caption>
+<caption> Improvement factor for an N-pulse delay-line canceler with optimum weights (solid curves) and binomial weights (dashed curves), as a function of the clutter spectral width.[(cite:Image9)]</caption>
  </figure>
@@ Line 954: / Line 966: @@
 <figure label>
 {{ :media:double_clutter.png?300x300 }}
-<caption> Improvement factor for a $3$-pulse (double-canceler) MTI cascaded with an 8-pulse doppler filter hank. or integrator.[(#13)]</caption>
+<caption> Improvement factor for a $3$-pulse (double-canceler) MTI cascaded with an 8-pulse doppler filter hank or integrator.[(cite:Image9)]</caption>
  </figure>
@@ Line 960: / Line 972: @@
-**Example Of An MTI Radar Processor**
+===== Moving Target Detector =====
+**Example Of An MTI Radar Processor**
 The **M**oving **T**arget **D**etector (**MTD**) is an MTI radar processor originally developed by the MIT Lincoln Laboratory for the FAA's Airport Surveillance Radars $A S R$.
@@ Line 971: / Line 993: @@
 <figure label>
 {{ :media:mtd.png?500 }}
-<caption> Simple block diagram of the Moving Target Detector (MTD) signal processor.[(#13)]</caption>
+<caption> Simple block diagram of the Moving Target Detector (MTD) signal processor.[(cite:Image9)]</caption>
  </figure>
-The input on the left is from the output of the $I$ and $Q$ A/D converters. The use of a three-pulse canceler ahead of the fi1ter: bank eliminates stationary clutter and thereby reduces the dynamic range required of the doppler filter-bank.
+The input on the left is from the output of the $I$ and $Q$ A/D converters. The use of a three-pulse canceler ahead of the filter: bank eliminates stationary clutter and thereby reduces the dynamic range required of the doppler filter-bank.
@@ Line 985: / Line 1007: @@
 <figure label>
 {{ :media:prf_radio.png?300 }}
-<caption> Detection of aircraft in rain using two prf's with a doppler filter bank.[(#13)]</caption>
+<caption> Detection of aircraft in rain using two prf's with a doppler filter bank.[(cite:Image9)]</caption>
  </figure>
@@ Line 994: / Line 1016: @@
-**Limitation of MTI Performance**
+**Limitation to MTI Performance**
@@ Line 1001: / Line 1023: @@
-  * **MTI Improvement Factor** ($I_C$) :
+ * **MTI Improvement Factor** ($I_C$) :
 The signal-to-clutter ratio at the output of the MTI system divided by the signal-to-clutter ratio at the input averaged uniformly over all target radial velocities of interest. (discussed earlier)
-  * **Subclutter Visibility** ($SCV$):
+ * **Subclutter Visibility** ($SCV$):
 The ratio by which a signal may be weaker than the coincident clutter and can be detected with the specified $P_d$ and $P_{fa}$. All radial velocities assumed equally likely.
@@ Line 1011: / Line 1033: @@
 $SCV = (C/S)_{in}$
-  * **Clutter Visibility Factor ($V_{OC}$)** :
+ * **Clutter Visibility Factor ($V_{OC}$)** :
 The Signal to Clutter ratio after filtering that provides the specified $P_d$ and $P_{fa}$.
@@ Line 1069: / Line 1091: @@
 <figure label>
  {{ :media:lim_mti.png?200 }}
-<caption> Power spectra of various clutter targets.[(#13)]</caption>
+<caption> Power spectra of various clutter targets.[(cite:Image9)]</caption>
  </figure>
@@ Line 1140: / Line 1162: @@
-A plot of $Eq.32$ for the double canceler is shown in $Fig.39$ The parameter describing the curves is ${f_p}λ $. Example PRF's and frequencies are shown. Several "representative" examples of clutter are indicated, based on published data for $σ_v$, which for the most part dates back to World War II
+A plot of $Eq.39$ for the double canceler is shown in $Fig.45$ The parameter describing the curves is ${f_p}λ $. Example PRF's and frequencies are shown. Several "representative" examples of clutter are indicated, based on published data for $σ_v$, which for the most part dates back to World War II
 <figure label>
 {{ :media:omega.png?430 }}
-<caption>Plot of double-canceler clutter improvement factor [(#13)]</caption>
+<caption>Plot of double-canceler clutter improvement factor [(cite:Image9)]</caption>
  </figure>
-Its a Plot of double-canceler clutter improvement factor [Eq.$32$] as a function of $σ_c$ = rms velocity spread of the clutter. The parameter is the product of the pulse repetition frequency ($f_p$) and the radar wavelength ($λ$).
+Its a Plot of double-canceler clutter improvement factor [Eq.$39$] as a function of $σ_c$ = rms velocity spread of the clutter. The parameter is the product of the pulse repetition frequency ($f_p$) and the radar wavelength ($λ$).
@@ Line 1171: / Line 1193: @@
 \begin{equation}
-G(θ) = G_0  exp [\frac{ - 2.776{θ}^2 }{ {θ_B}^2} ]
+G(θ) = G_0  exp [-{\frac{ 2.7726{θ}^2 }{ {θ_B}^2}} ]
 \end{equation}
@@ Line 1179: / Line 1201: @@
 \begin{equation}
-S_a = G_0  exp [\frac{ - 2.776({θ/ \dot{\theta }_s})^2 }{ (\frac{θ_B}{\dot{\theta }_s})^2} ]
+S_a = G_0  exp [-{\frac{  2.7726({θ/ \dot{\theta }_s})^2 }{ (\frac{θ_B}{\dot{\theta }_s})^2}} ]
 \end{equation}
@@ Line 1188: / Line 1210: @@
 \begin{equation}
-S_a = K  exp [\frac{ - 2.776 {t^2} }{ {t_0}^2} ] = K_1 exp [ \frac{{-π^2}{f^2}{t_0}^2}{ 2.776 }]
+S_a = K  exp [-{\frac{  2.7726 {t^2} }{ {t_0}^2} }] = K_1 exp [-{ \frac{{π^2}{f^2}{t_0}^2}{ 2.7726 }}]
 \end{equation}
-where $K$ = constant. Since this is a Gaussian function, the exponent is of the form $ f^2 /2{σ_f}^2 $; where $σ_f$ = standard deviation. Therefore
+where $K$ = $4ln2= 2.7726$. Since this is a Gaussian function, the exponent is of the form $ f^2 /2{σ_f}^2 $; where $σ_f$ = standard deviation. Therefore
@@ Line 1209: / Line 1231: @@
 <figure label>
 {{ :media:gaussian_shape.png?430 }}
-<caption> Limitation to improvement factor due to a scanning antenna. Antenna pattern assumed to be of gaussian shape.[(#13)]</caption>
+<caption> Limitation to improvement factor due to a scanning antenna. Antenna pattern assumed to be of gaussian shape.[(cite:Image9)]</caption>
  </figure>
@@ Line 1228: / Line 1250: @@
 <figure label>
 {{:media:a11.png?311 }}{{ :media:b11.png?340}}
-<caption> Effect of limit level on the improvement factor for ($a$) two-pulse delay-line canceler and ($b$) three-pulse delay-line canceler. C/L = ratio of rms clutter power to limit level.[(#13)]</caption>
+<caption> Effect of limit level on the improvement factor for ($a$) two-pulse delay-line canceler and ($b$) three-pulse delay-line canceler. $C/L$ = ratio of RMS clutter power to limit level.[(cite:Image9)]</caption>
  </figure>
@@ Line 1237: / Line 1260: @@
 When the MTI improvement factor is not great enough to reduce the clutter sufficiently..the clutter residue will appear on the display and prevent the detection of aircraft targets whose cross sections are larger than the clutter residue.
-Whereby setting the limit level $ L$, relative to the noise $ N$, equal to the MTI improvement factor $I$ or $L/N = 1$. If the limit level relative to noise is set higher than the improvement factor. clutter residue obscures part of the display and If it is set too low there may be a " black hole " effect on the display. The limiter provides a constant false alarm rate **(CFAR)** and is essential to usable MTI performance.
+Whereby setting the limit level $L$, relative to the noise $N$, equal to the MTI improvement factor $I$ or $L/N = 1$. If the limit level relative to noise is set higher than the improvement factor. clutter residue obscures part of the display and If it is set too low there may be a " black hole " effect on the display. The limiter provides a **C**onstant **F**alse **A**larm **R**ate (**CFAR**)[(A **false alarm** is “an erroneous radar target detection decision caused by noise or other interfering signals exceeding the detection threshold”. In general, it is an indication of the presence of a radar target when there is no valid aim. The False Alarm Rate (FAR) is calculated using the following formula: $FAR=\frac{false targets per PRT}{Number of rangecells}$)] and is essential to usable MTI performance.
 Unfortunately, nonlinear devices such as limiters have side-effects that can degrade performance.
-An example of the effect of limiting is shown in the Figure, which plots the improvement factor for two-pulse and three-pulse cancelers within various levels of limiting. The abscissa applies to a Gaussian clutter spectrum that is generated either by clutter motion with standard deviation $ σ_v$, at a wavelength $λ$ and a prf $f_p $, or by antenna scanning modulation with a Gaussian-shaped beam and $n_B$ pulses between the half-power beamwidth of the one-way antenna pattern. The parameter $C/L$ is the ratio of the RMS clutter power to the receiver-IF limit level.
+An example of the effect of limiting is shown in the $Fig.47$, which plots the improvement factor for two-pulse and three-pulse cancelers within various levels of limiting. The abscissa applies to a Gaussian clutter spectrum that is generated either by clutter motion with standard deviation $ σ_v$, at a wavelength $λ$ and a prf $f_p $, or by antenna scanning modulation with a Gaussian-shaped beam and $n_B$ pulses between the half-power beamwidth of the one-way antenna pattern. The parameter $C/L$ is the ratio of the RMS clutter power to the receiver-IF limit level.
 The loss of improvement factor increases with increasing complexity of the canceler.
-Thus the added complexity of higher-order cancelers is seldom justified in such situations. The linear analysis of MTI signal processors is therefore not adequate when limiting & employed and can lead to disappointing differences between theory and measurement of actual systems.
+Thus the added complexity of higher-order cancelers is not often justified in such situations. The linear analysis of MTI signal processors is therefore not enough when limiting & employed and can lead to disappointing differences between theory and measurement of actual systems.
@@ Line 1252: / Line 1275: @@
+**Termination of Moving Target Detection**
+The **M**oving **T**arget **D**etector, as we discussed earlier ,is able to optimize mobile targets in the presence of white addictive and clutter or improves target resolution.
+The output of the receiver is a signal, which contains the required target plus various forms of noise and clutter. In the case of the MTI output, this clutter residue is the result of imperfect cancellation due to various factors such as equipment instability, antenna modulation, lack of dynamic range or Doppler content within the clutter itself. The detection process separates the required target from the noise and clutter. Detectors are normally designed to carry out this process with a constant false alarm rate (CFAR).
+The diagram shows the location of the detector in the chain of signal processing. This device forms the information on a point like target as a digital report. The up to this point existing information about the analog value (or digital description of) of the received power in a particular binary cell will be transformed to information about the coordinates of a target. The value of the power is included in this report mostly.
+The important procedure is, that up to this point all binary cells (containing the received power) must be processed. After the detector exist only reports about selected binary cells. However, there may exist several reports about a single target, generated by adjacent binary cells. This will processed in the next device.
+<figure label>
+{{ :media:termination_of_mti_mtd.png?500 }}
+<caption> Part of block diagram(information flow)[(cite:Image3)]</caption>
+ </figure>
+Until now its simply discused about MTI performance limitiation ,MTD device operation and using different filters or transformation.deeper discussion on the Doppler frequency and adaptive thresholds on the different filters ,etc. __is presented in__
-More information is presented in **Modern Radar System Analysis** by **David K.Barton** chapter $6$.
+    *  **Modern Radar System Analysis**, Author: David K.Barton ,chapter $6$ .
+    *  **Advanced radar techniques and systems**, Author: Gaspare Galati ,chapter $12$ .