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Doppler radio direction finding

April 13, 2024

Doppler radio direction finding, also known as Doppler DF, is a radio direction finding method that generates accurate bearing information with a minimum of electronics. It is best suited to VHF and UHF frequencies, and takes only a short time to indicate a direction. This makes it suitable for measuring the location of the vast majority of commercial, amateur, and automated broadcasts. Doppler DF is one of the most widely used direction finding techniques. Other direction finding techniques are generally used only for fleeting signals, or longer or shorter wavelengths.

The Doppler DF system uses the Doppler effect to determine whether a moving receiver antenna is approaching or receding from the source. Early systems used antennas mounted on spinning disks to create this motion. In modern systems, the antennas are not moving physically, but electrically, by rapidly switching between a set of several antennas. As long as the switching occurs rapidly enough, which is easy to arrange, the Doppler effect will be strong enough to determine the direction of the signal. This variation is known as pseudo-Doppler DF, or sometimes sequential phase DF. This newer technique is so widely used that it is often the Doppler DF seen in most references.[1]

Direction finding edit

Early radio direction finding (RDF) solutions used highly directional antennas with sharp "nulls" in the reception pattern.[2] The operator rotated the antenna looking for points where the signal either reached a maximum, or more commonly, suddenly disappeared or "nulled". A common RDF antenna design is the loop antenna, which is simply a loop of wire with a small gap in the circle, typically arranged to rotate around the vertical axis with the gap at the bottom.[3] Some systems used dipole antennas instead of loops. Before the 1930s, radio signals were generally in what would today be known as the long wave spectrum. For the effective reception of these signals, very large antennas are needed. Direction finding with rotating antennas is difficult at these wavelengths due to the size of the antennas.[4][5]

A great advance in RDF technique was introduced in the form of the Bellini-Tosi direction finder system, which replaced the rotation of the antenna with the rotation of a small coil of wire connected to two non-moving loop antennas. The loop antennas were similar to those used in earlier systems but fixed in position, set at right angles to each other to form a cross-shaped arrangement. Each antenna will produce a different output whose relative strengths depend on how close the signal is to either antenna's null. These signals were sent to two coils of wire, the field coils, also arranged at right angles. These re-created the original signals in a much smaller space, about the size of a soda can. By rotating a small loop antenna, the sense coil, in the space between the two crossed field coils, one could perform DF. In effect, it recreated the traditional technique at a much smaller scale, allowing the main antennas to be built at any size.[6]

Robert Watson-Watt introduced the next major advance in direction finding as the "huff-duff" system, a nickname for high-frequency direction finding. Huff-duff also used crossed antennas, often an Adcock antenna,[7] but sent their output to the two channels of an oscilloscope. The relative strengths and phases of the two signals deflected the X and Y locations of the oscilloscope's electron beam by different amounts, causing an ellipse or figure-8 to appear on the screen, with the long axis indicating the direction of the signal.[8] The readout was essentially instantaneous and proved able to easily detect even short transmissions. Huff-duff was used in about one-quarter of all successful U-boat sinking.[9]

Both of these systems have drawbacks. The Bellini-Tosi system still has moving parts, albeit small ones, but has the more major limitation that it requires the operator to hunt for the signal, which may take several minutes. Huff-duff provides a direct and immediate indication of the signal direction, but only at the cost of requiring an oscilloscope or similar display system with an equally fast response. Both require two closely matched receivers and amplifiers, and often a third for the "sense" antenna if used.[10]

Doppler effect edit

If one places an antenna on a moving platform like the roof of a truck, the movement of the truck will cause the Doppler effect to shift the frequency of the signal upward as it moves towards the signal, or downward as it moves away. When the truck is driving at right angles to the signal, or not moving at all, there will be no shift.[11] If the truck is driven around a circular track, there will be times when it approaches the signal, moves away from it, or moves at right angles. This will produce a rising and falling frequency shift of the target signal, producing a frequency modulated (FM) signal known as the Doppler sine wave.[12] The FM signal has the same frequency as the rotational speed of the vehicle.[11][13]

The magnitude of the shift is a function of the wavelength of the signal and the angular velocity of the antenna:

S = r W/λ

Where S is the Doppler shift in frequency (Hz), r is the radius of the circle, W is the angular velocity in radians per second, λ is the target wavelength and c is the speed of light in meters per second.[13] Converting to more common units:

To convert Hz to radians per second, multiply by 6.28 (2 pi)
To convert MHz to Hz, multiply by 1 million
Eliminating the constants gives (6.28 × 1000000) / 300000000 = 1/0.02093... ~= 48

Such that:

S = r Fr Fc/ 48

Where Fr is the frequency of rotation in Hz and Fc is the target frequency in MHz.[13][a]

Consider the example truck hunting an FM radio station at 101.5 MHz while driving around a 100 metres (330 ft) wide pad (50 m radius) at 25 kilometres per hour (16 mph). The circumference of the pad is 2π×50 or 314 m, and its velocity in m/s is 25,000 / 60 / 60 ~= 7 m/s, so the truck completes one circuit in 314 / 7 = 45 seconds. Fr is therefore 145. Feeding that into the formula above, the frequency shift is:

S = 50 × 0.0222... × 101.8/ 48 = 2.4 Hz

This amount of frequency shift is too small to be accurately measured. To improve the detection odds, the product r W must be increased. For this reason, Doppler DF systems normally mount their antennas on a small disk that is spun at high speed using an electric motor. Performing the same calculation using an antenna mounted to a 50 centimetres (20 in) diameter disk spinning at 1000 Hz results in:

S = .25 × 1000 × 101.8/ 48 = 530 Hz

Which is easily detected. Nevertheless, such a rotation speed, 60,000 rpm, demands precision systems. Because the antennas have to move at very high speeds, this technique is only really useful for higher frequency signals where the antennas can be shorter[b] and the higher Fc produces a larger dividend.[13]

Early examples of Doppler DF systems date to at least 1941,[14] and they were used in the United Kingdom for hunting out German early warning radars, which operated at 250 MHz in the 1.25-meter band. By 1943, examples were available that worked in the UHF region, used to find the German Würzburg radars operating at 560 MHz.[15]

A significant advantage of this technique is that it requires only a single receiver, amplifier, and the appropriate FM demodulator. In contrast, huff-duff and B-T systems require two closely matched receivers, one for each antenna pair, and often a third for a sense channel.[7] Widespread civilian use of the technique did not start until the introduction of practical circuits for the quadrature detector and phase-locked loop, both introduced after the war, which greatly simplified the reception of FM signals. Its use roughly follows the spread of FM radio, which also used these techniques.[11]

Pseudo-Doppler edit

To further simplify the system, it is possible to simulate the movement of the antenna with a small amount of additional electronics. This is the pseudo-Doppler direction finding technique.[16]

Consider a pair of omnidirectional antennas receiving a signal from a target transmitter. As the signal propagates past the receiver, the amplitude of the signal at the antennas rises and falls. At long distances from the transmitter, well into the "far field", the wavefronts can be considered to be parallel.[17] If the two antennas are arranged perpendicular to the line to the target, the phase difference between them is zero, whereas if they are arranged parallel to the line, the phase difference will be a function of the distance between them and the wavelength of the signal.[17]

For this example, consider the two antennas to be located 14 of the target wavelength apart and aligned parallel to it. If the two antennas were sampled instantaneously, the difference in phase between them would always be the same, 90 °. But if one instead switches the input from one antenna to the other, there will always be some inherent delay during which time the signal continues to move past the two antennas. In this case, if the original sample was taken when the peak of the wavefront was at the nearer antenna and the system then switched to the farther one, the phase would not be 90 ° but somewhat smaller, because the wavefront approached the second antenna during that time.[13]

Now consider a series of such antennas arranged around the circumference of a circle, and a switch that connects to the antennas in turn in a clockwise fashion. If the target signal is at the midnight position, then the phase shift will be increased when the switching is moving "forward" between the 7 and 11 o'clock positions and reduced when moving "away", between 1 and 5. When switching between antennas perpendicular to the line to the signal, 11 to 1 and 5 to 7, the shift will be a constant value.[13]

The signal from the antennas is sent into a single receiver, resulting in a series of pulses whose amplitude depends on the phase at the instant of sampling. That signal is then smoothed to produce a sine wave.[18] That sine wave is modulated exactly as it would be in the case of a single moving antenna. In the case of the moving antenna, the frequency shifts because the antenna is moving through the wavefront as it passes, whereas, in the pseudo-Doppler case, this is accomplished by timing the samples to simulate the movement of a single antenna. The direction to the target transmitter can then be determined in the same fashion as the moving-antenna case, by comparing the phase of this signal to a reference signal. In this case, the reference is the clock signal triggering the switch.[13]

Because it has no moving parts and can be built using simple electronics, the pseudo-Doppler technique is very popular. Whilst not quite as fast as to measure the huff-duff system, in modern systems the measurement is so rapid that there is little practical difference between the two concepts. Pseudo-Doppler has a significant advantage in that the antenna system is much simpler, using monopole antennas, and if the switching system is located on the antenna, only a single wire runs back to the receiver and thus only one amplifier is required.[16] Because this technique is so widely used it is often referred to simply as Doppler DF, the "pseudo" rarely being added.[13]

The main disadvantage of the technique is the requirement for more signal processing. Because the "movement" in pseudo-Doppler proceeds in steps, the resulting signal is not as smooth as it is in the case of a moving antenna. This results in a signal with considerable numbers of sidebands that have to be filtered out. The switching system also introduces electronic noise, further confusing the output.[19] Modern signal processing can easily reduce these effects to insignificance.[16]

Notes edit

  1. ^ Moell was written in 1978 and uses inches for radius, resulting in a conversion constant of 1880, this has been converted to meters for modern readers by dividing by ~39 in/m.
  2. ^ For a variety of reasons, radio antennas have to be about 12 the length of the wavelength they are trying to receive.

References edit

Citations edit

  1. ^ "Pseudo-Doppler Direction Finder Amanda Ke, Melissa Li, Jimmy Mawdsley" (PDF).
  2. ^ Army 1977, p. 3.3.
  3. ^ Sadler 2010, p. 4.
  4. ^ Yeang 2013, p. 188.
  5. ^ Moell 1987, p. 28.
  6. ^ Army 1977, p. 3.17.
  7. ^ a b Sadler 2010, p. 6.
  8. ^ Army 1977, p. 3.36.
  9. ^ Bauer, Arthur O. (27 December 2004). "HF/DF An Allied Weapon against German U-Boats 1939–1945" (PDF). p. 1. Retrieved 2008-01-26.
  10. ^ Sadler 2010, pp. 5–6.
  11. ^ a b c Army 1977, p. 3.26.
  12. ^ Moell 1987, p. 123.
  13. ^ a b c d e f g h Moell 1987, p. 121.
  14. ^ US Expired 2414798, Horace Budenbom, "Direction finder", published 28 January 1947, assigned to Bell Labs 
  15. ^ Rembovsky et al. 2009, p. 21.
  16. ^ a b c Sadler 2010, p. 7.
  17. ^ a b Army 1977, p. 3.27.
  18. ^ Poisel 2012, p. 376.
  19. ^ Moell 1987, p. 137.

Bibliography edit

  • Sadler, David (25 February 2010). (PDF) (Technical report). Roke Manor Research. Archived from the original (PDF) on 9 August 2017.
  • Moell, Joseph (1987). Transmitter Hunting: Radio Direction Finding Simplified. TAB Books. ISBN 9780830627011.
  • Radio Direction Finding. United States Army. 1977.
  • Rembovsky, Anatoly; Ashikhmin, Alexander; Kozmin, Vladimir; Smolskiy, Sergey (2009). Radio Monitoring: Problems, Methods and Equipment. Springer. ISBN 9780387981000.
  • Poisel, Richard (2012). Antenna Systems and Electronic Warfare Applications. Artech House. ISBN 9781608074846.
  • Yeang, Chen-Pang (2013). Probing the Sky with Radio Waves. University of Chicago Press. ISBN 9780226015194.

April 13, 2024
doppler, radio, direction, finding, this, article, tone, style, reflect, encyclopedic, tone, used, wikipedia, wikipedia, guide, writing, better, articles, suggestions, january, 2022, learn, when, remove, this, template, message, also, known, doppler, radio, di. This article s tone or style may not reflect the encyclopedic tone used on Wikipedia See Wikipedia s guide to writing better articles for suggestions January 2022 Learn how and when to remove this template message Doppler radio direction finding also known as Doppler DF is a radio direction finding method that generates accurate bearing information with a minimum of electronics It is best suited to VHF and UHF frequencies and takes only a short time to indicate a direction This makes it suitable for measuring the location of the vast majority of commercial amateur and automated broadcasts Doppler DF is one of the most widely used direction finding techniques Other direction finding techniques are generally used only for fleeting signals or longer or shorter wavelengths The Doppler DF system uses the Doppler effect to determine whether a moving receiver antenna is approaching or receding from the source Early systems used antennas mounted on spinning disks to create this motion In modern systems the antennas are not moving physically but electrically by rapidly switching between a set of several antennas As long as the switching occurs rapidly enough which is easy to arrange the Doppler effect will be strong enough to determine the direction of the signal This variation is known as pseudo Doppler DF or sometimes sequential phase DF This newer technique is so widely used that it is often the Doppler DF seen in most references 1 Contents 1 Direction finding 2 Doppler effect 3 Pseudo Doppler 4 Notes 5 References 5 1 Citations 5 2 BibliographyDirection finding editEarly radio direction finding RDF solutions used highly directional antennas with sharp nulls in the reception pattern 2 The operator rotated the antenna looking for points where the signal either reached a maximum or more commonly suddenly disappeared or nulled A common RDF antenna design is the loop antenna which is simply a loop of wire with a small gap in the circle typically arranged to rotate around the vertical axis with the gap at the bottom 3 Some systems used dipole antennas instead of loops Before the 1930s radio signals were generally in what would today be known as the long wave spectrum For the effective reception of these signals very large antennas are needed Direction finding with rotating antennas is difficult at these wavelengths due to the size of the antennas 4 5 A great advance in RDF technique was introduced in the form of the Bellini Tosi direction finder system which replaced the rotation of the antenna with the rotation of a small coil of wire connected to two non moving loop antennas The loop antennas were similar to those used in earlier systems but fixed in position set at right angles to each other to form a cross shaped arrangement Each antenna will produce a different output whose relative strengths depend on how close the signal is to either antenna s null These signals were sent to two coils of wire the field coils also arranged at right angles These re created the original signals in a much smaller space about the size of a soda can By rotating a small loop antenna the sense coil in the space between the two crossed field coils one could perform DF In effect it recreated the traditional technique at a much smaller scale allowing the main antennas to be built at any size 6 Robert Watson Watt introduced the next major advance in direction finding as the huff duff system a nickname for high frequency direction finding Huff duff also used crossed antennas often an Adcock antenna 7 but sent their output to the two channels of an oscilloscope The relative strengths and phases of the two signals deflected the X and Y locations of the oscilloscope s electron beam by different amounts causing an ellipse or figure 8 to appear on the screen with the long axis indicating the direction of the signal 8 The readout was essentially instantaneous and proved able to easily detect even short transmissions Huff duff was used in about one quarter of all successful U boat sinking 9 Both of these systems have drawbacks The Bellini Tosi system still has moving parts albeit small ones but has the more major limitation that it requires the operator to hunt for the signal which may take several minutes Huff duff provides a direct and immediate indication of the signal direction but only at the cost of requiring an oscilloscope or similar display system with an equally fast response Both require two closely matched receivers and amplifiers and often a third for the sense antenna if used 10 Doppler effect editIf one places an antenna on a moving platform like the roof of a truck the movement of the truck will cause the Doppler effect to shift the frequency of the signal upward as it moves towards the signal or downward as it moves away When the truck is driving at right angles to the signal or not moving at all there will be no shift 11 If the truck is driven around a circular track there will be times when it approaches the signal moves away from it or moves at right angles This will produce a rising and falling frequency shift of the target signal producing a frequency modulated FM signal known as the Doppler sine wave 12 The FM signal has the same frequency as the rotational speed of the vehicle 11 13 The magnitude of the shift is a function of the wavelength of the signal and the angular velocity of the antenna S r W lWhere S is the Doppler shift in frequency Hz r is the radius of the circle W is the angular velocity in radians per second l is the target wavelength and c is the speed of light in meters per second 13 Converting to more common units To convert Hz to radians per second multiply by 6 28 2 pi To convert MHz to Hz multiply by 1 million Eliminating the constants gives 6 28 1000000 300000000 1 0 02093 48Such that S r Fr Fc 48Where Fr is the frequency of rotation in Hz and Fc is the target frequency in MHz 13 a Consider the example truck hunting an FM radio station at 101 5 MHz while driving around a 100 metres 330 ft wide pad 50 m radius at 25 kilometres per hour 16 mph The circumference of the pad is 2p 50 or 314 m and its velocity in m s is 25 000 60 60 7 m s so the truck completes one circuit in 314 7 45 seconds Fr is therefore 1 45 Feeding that into the formula above the frequency shift is S 50 0 0222 101 8 48 2 4 HzThis amount of frequency shift is too small to be accurately measured To improve the detection odds the product r W must be increased For this reason Doppler DF systems normally mount their antennas on a small disk that is spun at high speed using an electric motor Performing the same calculation using an antenna mounted to a 50 centimetres 20 in diameter disk spinning at 1000 Hz results in S 25 1000 101 8 48 530 HzWhich is easily detected Nevertheless such a rotation speed 60 000 rpm demands precision systems Because the antennas have to move at very high speeds this technique is only really useful for higher frequency signals where the antennas can be shorter b and the higher Fc produces a larger dividend 13 Early examples of Doppler DF systems date to at least 1941 14 and they were used in the United Kingdom for hunting out German early warning radars which operated at 250 MHz in the 1 25 meter band By 1943 examples were available that worked in the UHF region used to find the German Wurzburg radars operating at 560 MHz 15 A significant advantage of this technique is that it requires only a single receiver amplifier and the appropriate FM demodulator In contrast huff duff and B T systems require two closely matched receivers one for each antenna pair and often a third for a sense channel 7 Widespread civilian use of the technique did not start until the introduction of practical circuits for the quadrature detector and phase locked loop both introduced after the war which greatly simplified the reception of FM signals Its use roughly follows the spread of FM radio which also used these techniques 11 Pseudo Doppler editTo further simplify the system it is possible to simulate the movement of the antenna with a small amount of additional electronics This is the pseudo Doppler direction finding technique 16 Consider a pair of omnidirectional antennas receiving a signal from a target transmitter As the signal propagates past the receiver the amplitude of the signal at the antennas rises and falls At long distances from the transmitter well into the far field the wavefronts can be considered to be parallel 17 If the two antennas are arranged perpendicular to the line to the target the phase difference between them is zero whereas if they are arranged parallel to the line the phase difference will be a function of the distance between them and the wavelength of the signal 17 For this example consider the two antennas to be located 1 4 of the target wavelength apart and aligned parallel to it If the two antennas were sampled instantaneously the difference in phase between them would always be the same 90 But if one instead switches the input from one antenna to the other there will always be some inherent delay during which time the signal continues to move past the two antennas In this case if the original sample was taken when the peak of the wavefront was at the nearer antenna and the system then switched to the farther one the phase would not be 90 but somewhat smaller because the wavefront approached the second antenna during that time 13 Now consider a series of such antennas arranged around the circumference of a circle and a switch that connects to the antennas in turn in a clockwise fashion If the target signal is at the midnight position then the phase shift will be increased when the switching is moving forward between the 7 and 11 o clock positions and reduced when moving away between 1 and 5 When switching between antennas perpendicular to the line to the signal 11 to 1 and 5 to 7 the shift will be a constant value 13 The signal from the antennas is sent into a single receiver resulting in a series of pulses whose amplitude depends on the phase at the instant of sampling That signal is then smoothed to produce a sine wave 18 That sine wave is modulated exactly as it would be in the case of a single moving antenna In the case of the moving antenna the frequency shifts because the antenna is moving through the wavefront as it passes whereas in the pseudo Doppler case this is accomplished by timing the samples to simulate the movement of a single antenna The direction to the target transmitter can then be determined in the same fashion as the moving antenna case by comparing the phase of this signal to a reference signal In this case the reference is the clock signal triggering the switch 13 Because it has no moving parts and can be built using simple electronics the pseudo Doppler technique is very popular Whilst not quite as fast as to measure the huff duff system in modern systems the measurement is so rapid that there is little practical difference between the two concepts Pseudo Doppler has a significant advantage in that the antenna system is much simpler using monopole antennas and if the switching system is located on the antenna only a single wire runs back to the receiver and thus only one amplifier is required 16 Because this technique is so widely used it is often referred to simply as Doppler DF the pseudo rarely being added 13 The main disadvantage of the technique is the requirement for more signal processing Because the movement in pseudo Doppler proceeds in steps the resulting signal is not as smooth as it is in the case of a moving antenna This results in a signal with considerable numbers of sidebands that have to be filtered out The switching system also introduces electronic noise further confusing the output 19 Modern signal processing can easily reduce these effects to insignificance 16 Notes edit Moell was written in 1978 and uses inches for radius resulting in a conversion constant of 1880 this has been converted to meters for modern readers by dividing by 39 in m For a variety of reasons radio antennas have to be about 1 2 the length of the wavelength they are trying to receive References editCitations edit Pseudo Doppler Direction Finder Amanda Ke Melissa Li Jimmy Mawdsley PDF Army 1977 p 3 3 Sadler 2010 p 4 Yeang 2013 p 188 Moell 1987 p 28 Army 1977 p 3 17 a b Sadler 2010 p 6 Army 1977 p 3 36 Bauer Arthur O 27 December 2004 HF DF An Allied Weapon against German U Boats 1939 1945 PDF p 1 Retrieved 2008 01 26 Sadler 2010 pp 5 6 a b c Army 1977 p 3 26 Moell 1987 p 123 a b c d e f g h Moell 1987 p 121 US Expired 2414798 Horace Budenbom Direction finder published 28 January 1947 assigned to Bell Labs Rembovsky et al 2009 p 21 a b c Sadler 2010 p 7 a b Army 1977 p 3 27 Poisel 2012 p 376 Moell 1987 p 137 Bibliography edit Sadler David 25 February 2010 HF Radio Direction Finding PDF Technical report Roke Manor Research Archived from the original PDF on 9 August 2017 Moell Joseph 1987 Transmitter Hunting Radio Direction Finding Simplified TAB Books ISBN 9780830627011 Radio Direction Finding United States Army 1977 Rembovsky Anatoly Ashikhmin Alexander Kozmin Vladimir Smolskiy Sergey 2009 Radio Monitoring Problems Methods and Equipment Springer ISBN 9780387981000 Poisel Richard 2012 Antenna Systems and Electronic Warfare Applications Artech House ISBN 9781608074846 Yeang Chen Pang 2013 Probing the Sky with Radio Waves University of Chicago Press ISBN 9780226015194 Retrieved from https en wikipedia org w index php title Doppler radio direction finding amp oldid 1216776082, wikipedia, wiki, book, books, library,

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