Introduction to Naval Weapons Engineering

Radar Principles and Systems

1. Calculate the duty cycle of a radar which transmits a 1.5 ms pulse at a PRF of 8 kHz. If the peak power of this radar is 500 kilowatts, what is the average power? What is the resting time?
   
   

   Eqn (2-1). The duty cycle is the result of dividing the pulse width (1.5 ms) by the pulse repetition time (1/8000 Hz) or multiplying the pulse width by the pulse repetition frequency. (1.5 x 10^-6 seconds) x (8 x 10³ second^-1) = 0.012 The duty cycle is the ratio of average power to peak power. Therefore, if the duty cycle is 0.012, and the peak power is 500 kilowatts, the average power can be obtained by multiplying the duty cycle by the peak power. (0.012)(500 x 10³ watts) = 6 kilowatts. From Figure 2-1, the resting time is the difference be- tween the pulse repetition time (the reciprocal of the pulse repetition frequency) and the pulse width. Rest Time = 1/8000 Hz - 1.5 x 10^-6 s = 1.24 x 10^-4 s = 124 ms

2. A pulsed radar has a duty cycle of .016. If the resting time is 380 ms, what is the pulse width? What is the PRF? What is the minimum range, in meters, of this radar?
   
   

   Eqn (2-1) For pulse repetition time (PRT) substitute rest time plus pulse width (RT + PW). Solve for PW. PW = 6.18 ms

3. If a CRT is designed so that the spot traverses the indicator face in 900 ms, what range could be indicated by a spot deflection half way across the indicator?
   
   

   Eqn (2-3) Solve equation (2-3) for R to find the range indicated by the full width of the screen. R = 1/2(3.0 x 10⁸ m/s)(900 x 10^-6 s ) = 135 Km A deflection halfway across the indicator represents half of 135 km, or 67.5 km.

4. List the seven basic pulse radar components and briefly describe the function of each.
   
   

   Synchronizer

   The timing unit of the system. As such it determines the PRF and coordinates the sweep on the sweep on the indicator with the firing of the transmitter.

   Transmitter

   Generates RF energy of the desired frequency and delivers it to the antenna system.

   Antenna System

   Broadcasts transmitter energy in desired pattern into space and receives return energy.

   Duplexer

   Consists of TR (Transmit-Receive) and a ATR (Anti-Transmit-Receive) device. Allows the use of a single antenna for Xmit and Receive.

   Receiver

   Amplifies weak return signal and transforms it into a form useful for dispaly on the indicator.

   Display

   Provides a method for presenting desired target information in a useful form for the operator.

   Power Supply

   Supplies power!

5. A target is closing on a radial of a radar site with a relative velocity of 200 knots. The radar transmits continuous wave energy at a wavelength of 5 cm. What will the Doppler shift of the target be? What will the Doppler shift be if the target alters its course by 45^o (closure speed reduced)?
   
   

   From appendix B: 1 knot = .508 m/s, so 200 kts = 10160 cm/s Use Eqn (2-4) Frequency shift = (2)(10160 cm/s)/(5cm) = 4.06 kHz for a course change of 45^o, the velocity component in the closure direction becomes 10160cos(45^o)=7184cm/s Frequency shift = 2(7184 cm/s)/(5 cm) = 2.87 kHz

6. Will the Doppler shift for an opening target indicate an increase or decrease in frequency? Why?

   Decrease, from (Eqn 2-4), if S is "negative", that is, going away, then the frequency shift is a negative value.

7. Why can't a CW radar measure range? What is the main advantage of a CW radar?
   
   

   Range is measured by noting the round trip time for a pulse of radar energy. Since a CW radar transmits continuously, there is no means of measuring the round trip time and therefore no direct means of measuring range. The principle advantage of a CW radar is its inherent ability to recognize moving targets. It is safe to say that any target which represents some threat will also be in motion.

8. Why can a better angle measurement be achieved with a narrow beam than a wide beam? Which would be more suitable for searching for targets? Why?
   
   

   Since signal strength changes are more pronounced as the target moves toward the edge of the beam, the closer to the edge of the target is while being tracked the easier it is to detect a change in angle. Those large changes of signal strength occur closer to the axis in a narrow beam than in a wide beam resulting in better tracking accuracy. Wide beam. Because a narrow beam would cover too small an area in space to be useful in initially locating potential threats. A narrow beam is much better suited for target tracking and fire control solutions where accuracy is the main consideration. Search radars do not require any particular degree of resolution since their main function is to determine target presence only. Once this is accomplished, a narrow beam would be used for tracking.

9. What is the difference between a broadside and end-fire array? Explain how the broadside array of Figure (2-17) could be modified to become an end-fire array.
   
   

   In a broadside array, all elements are transmitting in phase. If each element were stimulated out of phase with its immediate neighbor, by an amount equal to the portion of a wavelength that separates adjacent elements, an end-fire array would result.

10. Explain the function of a parasitic reflector.
    
    

    The parasitic reflector is employed in some radar antenna systems as a means of concentrating the radiated energy in a desired direction. Without a device to serve this purpose, an array type radar antenna would broadcast two equal main beams in opposite directions. When a conducting element is placed in an electric field, a voltage will be induced in the element. When this field varies, as around a radiating dipole, the variation in the induced voltage in the conductor (driven element) will cause it to radiate as well, but with a phase shift. Proper positioning of the driven element in the vicinity of the array will therefore set up interference which will tend to cancel the field in one direction and rein- force it in another, thereby allowing for a single, stronger main beam.

11. Discuss the advantages of a double lobe system over a single lobe system in terms of azimuth determination.
    
    

    Single lobe systems are suitable for determining target bearing as long as no requirement exists for a high degree of accuracy. Once a strong signal is received, indicating a roughly centered beam, the single lobe system is at the limit of its value. This is because the teardrop shape of a radar beam makes it extremely difficult to fine tune; the antenna azimuth to the point of exact maximum return. A double lobe system does not require the determination of maximum return, but rather the azimuth at which the return signal is equal for each lobe. From an operator standpoint, it is considerably less difficult to match two signals where there is a constant reference than to determine the maximum of one signal where there is a variable reference. The double lobe system has an additional advantage in that, when the azimuth setting is close to correct, the return from each lobe is coming from nearer the side of the lobes where variations in signal strength are more pronounced. This makes it considerably less difficult to fine tune the antenna azimuth.

12. List and briefly discuss three methods of determining target elevation.
    
    
    1. Threshold-pickup A low-accuracy single lobe method which makes use of signals reflected from the earth's surface. The path length difference between the direct radar energy and the reflected radar energy causes cancellation at some points in space and reinforcement at others. The net result is a "layer of lobes" in space. This antenna would be fixed in elevation and an operator would have a fade chart to use which would give an elevation based upon range at which the first discernible signal appears.
    2. Signal-comparison Similar to threshold-pickup except that two lobes are utilized and the ratio of signal strengths as well as target range are used to determine altitude. This method is considerably more accurate than the threshold-pickup method.
    3. Tilted-antenna This method is similar to the single lobe method for determining azimuth. The antenna Πis elevated such that no portion of the lobe is reflected from the surface. The elevation angle of the antenna at target acquisition and the range can be trigonometric- ally combined to determine target altitude.
13. What is the primary source of radar noise? Discuss the relationship between signal-to-noise ratio and bandwidth.
    
    

    The greatest percentage of noise is generated with the electronic circuitry of the radar, particularly in the input to the receiver. A common source of this noise results from the random motion of electrons within electrical elements. Since there will be motion at any temperature above absolute zero, it is difficult to eliminate such noise (Johnson noise). The wider the bandwidth, the greater the degree of noise that will be input to the receiver. Since noise exists at all frequencies, the broader the frequency range to which the receiver is tuned, then the higher the intensity level if the noise and the lower the signal-to-noise ratio.

14. What is the maximum unambiguous range for a radar with a PRF of 600 Hz? What PRF is required for maximum unambiguous range of 350 km?
    
    

    Use Eqn (2-3) For t, substitute the reciprocal of PRF, and solve for R. R = 1/2(3.0 x 10⁸m/sec)(600 s^-1)-1 = 250 km To determine the required PRF to achieved a maximum unambiguous range of 350 Km, substitute 350 km for R in Eqn (2-3) and solve for PRT. The required PRF is the reciprocal that results. PRF = [(2)(350x10³cm)/(3.0x10⁸m/sec)]-1 = 428.6 Hz

15. What is the minimum range for radar with a PW of 5 ms? What is the radar's range resolution?
    
    

    Use Eqn (2-3) Substitute PW for t. R = 1/2 (3.0 x 10⁸m/s)(5.0 x 10^-6 s) = 750 meters Assume a pulse compression ratio of 1.0. R_RES = R_min = 750 meters

16. Why is it advantageous to have a low duty cycle?
    
    

    Duty cycle is the ratio of average power to peak power. A low duty cycle would indicate low average power and high peak power. The low average power is desirable from the standpoint of equipment size and the high peak power is important for maximum return signal strength.

17. Why is there a requirement to have at least 10 return pulses (or echoes) to rate the target as valid?
    
    

    The probability of noise being generated in the same time space (i.e. Range) 10 or more times in a row is extremely low, therefore assuring returns are a target.

18. If the receiver has a receiver sensitivity of -83 dBm, what is the value of the minimum discernible signal (S_min)?
    
    

    Use Eqn (2-5) Substitute -83 dBm for receiver sensitivity and solve for S_min. S_min = log-110[1/10(-83)]=5.012 x 10^-9 mW = 5.012x10^-12 W

19. Given an antenna beam width of 3", a scan rate of 48^o/sec and a PRF of 200 Hz; how many pulses will be returned from a point target as the antenna scans through its beam width?
    
    

    Use Eqn (2-6) Substitute 3^o for q_B, 48^o/sec for q_S and 200 Hz for PRF. Solve for NB. NB = (3^o)(200 sec-1)/(48^o/sec) = 12.5 pulses

20. What is the directive gain for an antenna with a horizontal half power beam width of 2^o and a vertical half power beam width of 4^o?
    
    

    Use Eqn (2-8) Convert the beam widths to radius by dividing each value by 57.3^o. Substitute the beam widths into Eqn (2-8) and solve for G_D. G_D = [(4)( p)]/[(2/57.3)(4/57.3)] = 5157.4

21. Explain why the echo from an A-4 might be much stronger than the echo from a larger aircraft at the same range.
    
    

    The radar cross-section of any target will vary with aspect and reflecting qualities. A plan form view of an A-4 will appear much larger than a nose-on view of an A-3, for example.

22. Increasing the transmitter power of a radar by a factor of 5 will increase the maximum range by what percent?
    
    

    Use Eqn (2-17) Use Eqn (2-17) to find a ratio of values for R_max under the two conditions. Under the new conditions, P_t(new) = 5P_t(old). All other factors remain the same and cancel. R_o(new)/R_o(old)=[5P_t(old)/P_t(old)]1/4 = 1.495 Therefore increasing P_t by a factor of 5 results in a 49.5 % increase in range.

23. For a given target a radar has a maximum range of 100 km. If the sensitivity of the radar receiver deteriorates by 3 dB, what is the degraded maximum range for that target?
    
    

    Use Eqn (2-17) A 3dB loss in sensitivity equates to a revised sensitivity that's 1/2 the original sensitivity, or the revised S_min being twice the original S_min. As in problem 2-22, find a ratio of R_max under the two conditions of S_min. Under the new conditions S_min(new) = 2 S_min(old). All other factors cancel. R_new/R_old=[1/(2S_min(old)/1/Smin]1/4=(1/2)1/4=0.841. Therefore, the revised range is 84.1 Km

24. A given radar with a S_min = 10-9W can detect a target having a radar cross-section of 3 meter2 at a range of 40 miles. At what range can this same radar detect a 1 meter2 target if its Sensitivity is improved by 6 dB? Use Eqn (2-17)
    
    

    A 6dB improvement in sensitivity is a 4-fold improvement. Therefore, S_min(new) = 1/4 S_min(old) R_new/R_old=[(lm2/1/4Smin(old)/(3m2/Smin(old)]1/4=1.074 f Rold=40 miles, R_new=(1.074)(40 miles)=42.98 miles

25. A frequency modulated radar sweeps from 400 MHz to 800 MHz in 10 ms. What is the maximum unambiguous range which can be measured by this radar?
    
    

    Use Eqn (2-3) The maximum unambiguous range is 1/2 the distance that can be travelled by the radar energy during the time of one sweep from 400 to 800 MHz. Substitute 10 ms for t in Eqn (2-3) and solve for R. R = 1/2(3.0x10⁸ m/sec)(10x10^-6 sec) = 1.5KM.

26. What is the main feature which differentiates pulsed Doppler or MTI radars from pulse-echo radars?
    
    

    The pulse-echo radar is capable only of measuring the elapsed travel time of individual pulses, however, where the Pulse-Doppler/MTI radars are capable of measuring a shift in the frequency of the RF energy in the return pulse and are therefore sensitive to target velocity.

27. Discuss the difference between pulse-Doppler and MTI radars.
    
    

    Pulse-Doppler radars use filters to selectively pass Doppler frequencies. MTI radars use delay line and canceller to eliminate low/no Doppler frequency shifts.

28. A pulse-Doppler radar has a carrier frequency of 9 GHz and a PRF of 4000 Hz.
    
    
    1. What are its "blind" Doppler frequencies?
       
       

       f D = n PRF = n (4000 HZ) = 4000 HZ, 8000 HZ, 12000 HZ, etc.

    2. What radial target velocities would be undetected by the radar?
       
       

       Use Eqn (2-18) Find l using Eqn (1-1). l = (3.0x10⁸ m/sec)/(9x10⁹ sec^-1)=3.33 cm Solve Eqn (2-18) for V_t = n (4000 Hz) (3.33x10^-2 m)/2 = n 66.67 m/sec. Any integer multiple of 66.67 m/sec is undetectable by this system.

    3. What modification can be made to the radar that would eliminate blind speeds below 2000 knots (use PRF)?
       
       

       2000 KTS = 1016 m/s Let n = 1 Use Eqn (2-18) Substitute 1016 m/sec for V_t and 1 for n. Solve equations (2-18) for PRF. PRF=[(2)(1016 msec)]/[(1)(3.33x10^-2 m)]=61.02 kHz

    4. What would the maximum unambiguous range of the modified radar be?
       
       

       Use Eqn (2-3) Substitute the reciprocal of the PRF for t and solve for R. R=1/2(3.0x10⁸ m/sec)(6.102 x 10⁴sec^-1)-1=2.46 km

    5. What additional modification(s) would allow for an increase in maximum unambiguous range?
       
       

       Reduce frequency so that higher PRT's are possible.

29. A fighter aircraft in level flight on a heading of 090^oT and at an airspeed of 600 m/sec is operating a pulse-Doppler radar at a frequency of 800 MHz. A target is detected at the same altitude, bearing 000^oR, heading 030^oT at a speed of 300 m/sec.
    
    
    1. What is the relative radial velocity between the fighter and the target?
       
       

       Determine the angle between the fighter's course and its line of sight (LOS) to the target. (0^o). Determine the angle between the target's course and the LOS from fighter to target (120^o). The relative radial is determined by summing the velocity components along the LOS. S = S_ret+S_tgt = (600 m/s) cos(0^o) + ( 300 m/s) cos(120^o) = 450 m/s

    2. What will the resulting Doppler shift be?
       
       

       Use Eqn (2-4) Substitute the relative radial velocity just obtained into Eqn (2-4) and solve for the change in frequency. (Use Eqn (1-1) to determine lambda). Frequency shift = (2)(450 m/sec)/0.375 m) = 2.4 kHz

30. A pulse radar propagates the pulse train shown below. Each pulse has its frequency increased over the duration of the pulse width resulting in a pulse compression ratio of 100:1. What is the range resolution of this radar?
    
    

    Using Eqn (2-3, substitute PW for t, and solve for R_min. R_min = 1/2(3x10⁸ m/sec)(3x10^-6 sec) = 450m R_Res = R_max/PCR = 300 km/100 = 4.5 m

31. Why is it possible to achieve a more narrow beamwidth with a millimeter system than a microwave radar? (Microwave radar frequencies cover 800-1000 MHz.)
    
    

    Millimeter systems approach "light" wavelengths and there fore can use "lens" to create beams. Microwave radars require larger antennas and therefore are harder to focus or create beams.

32. The following table lists the characteristics of the components of a pulse-echo type surface search radar. Using the concepts presented in this chapter, complete this table.
    
    
    

    frequency, f	5600 MHz
    wave length, l	_____
    pulse width, PW	1.3m sec
    pulse repetition frequency, PRF	_____
    pulse repetition time, PRT	_____
    peak power	_____
    average power	_____
    duty cycle	8.3 x 10-4
    Antenna rotation rate, q	16 RPM
    Horizontal beamwidth, qB	_____
    vertical beam width, fB	4o
    effective aperture, Ae	0.9 m2
    power gain, G	3940
    directive gain, GD	_____
    number of returns per sweep, NB	9.9
    minimum discernible signal, MDS	-83dBm
    receiver sensitivity , Smin	_____
    maximum unambiguous range, Runamb	_____
    maximum theoretical range, Rmax	50 km
    minimum range, Rmin	_____
    range resolution, Rres	_____
    radar cross-section, s	5 m2

    Wavelength

    Use Eqn (1-1)
    l= (3.0 x 10⁸ m/sec)/(5600 x 10⁶ Hz) = 5.36 cm

    PRT

    Use Eqn (2-1)
    PRT = PW/DC = 1.3 msec/8.3x10^-4 = 1.57x10³ msec

    PRF

    PRF = 1/PRT = (1.57x10^-3sec)^-1 = 638.5 Hz

    Peak Power

    Hint, skip this and continue on to the end then solve.)
    Use Eqn (2-17)
    Rearrange Eqn (2-17) and solve for P_T. (Eqn (2-17) requires S_min; that's why you had to skip this)
    
    P_T = (S_min)(4p R²)2/GA_es = (5.012x10^-12)[(4 p)(50x10³m)²]2/(3940)(0.9)(5.0)
    
    P_T = 279KW

    Average Power

    Solve Eqn (2-1) for the average power ( P_ave ). P_ave = P_t
    DC = (279KW)(8.3 x 10-4) = 231.6W

    Directive Gain

    Use Eqn (2-6) and (2-8)
    Rearrange Eqn (2-6) to solve for q_B, the horizontal beam width. Change the scan rate (16 RPM) to ^o/sec as follows:
    scan rate =(16 revolutions/min)(360^o/revolution) (60 sec/min)^-1 = 96^o/sec.
    Solve Eqn (2-6) for q _B:
    q _B=(NB)(scan rate)/PRF=(9.9)(96^o/sec)/ (638.5 sec^-1) = 1.49^o
    Solve Eqn (2-8) for G_D, changing the beam widths to radians.
    G_D= (4p )/(4.0/57.3)(1.49/57.3) = 6929

    Minimum Discernible Signal

    Use Eqn (2-5) Substitute -83 dB for receiver sensitivity and solve for S_min = 10^[1/10(-83)] = 5.012 x 10^-12 W

    R_unamb

    Use Eqn (2-3) Substitute PRT for t, solve for R. R = 1/2(3.0x10⁸m/sec)(1.57x10^-3sec) = 235.5 km

    R_min

    Use Eqn (2-3) Substitute PW for t, solve for R. R = 1/2(3.0x10⁸m/sec)(1.3x10^-6sec) = 195 m

    R_res

    Assume no pulse compression. Rres = Rmin = 195m