The antenna was invented by Shintaro Uda of Tohoku Imperial University, Japan,^[5] in 1926 with a lesser role played by Hidetsugu Yagi.^[6][7]

However, the name "Yagi" has become more familiar, with the name of Uda who applied the idea in practice or established the conception through experiment is often omitted. This appears to have been due to the fact that Yagi based on Uda's pre-announcement^[5] and developed the principle of the absorption phenomenon he had announced,^[8] Yagi filing a patent on the new idea in Japan without Uda's name in it, and later transferring the patent to the Marconi Company in the UK.^[9] Incidentally, in the US, the patent was transferred to RCA Corporation.^[10]

Yagi antennas were first widely used during World War II in radar systems by the Japanese, Germans, British and US.^[7] After the war they saw extensive development as home television antennas.

The Yagi–Uda antenna typically consists of a number of parallel thin rod elements, each approximately a half wave in length. Often they are supported on a perpendicular crossbar or "boom" along their centers.^[2] Usually there is a single dipole driven element consisting of two collinear rods each connected to one side of the transmission line, and a variable number of parasitic elements, reflectors on one side and optionally one or more directors on the other side.^[2][3][4] The parasitic elements are not electrically connected to the transmission line, and serve as passive radiators, reradiating the radio waves to modify the radiation pattern.^[2] Typical spacings between elements vary from about 1⁄10 to 1⁄4 of a wavelength, depending on the specific design. The directors are slightly shorter than the driven element, while the reflector(s) are slightly longer.^[4] The radiation pattern is unidirectional, with the main lobe along the axis perpendicular to the elements in the plane of the elements, off the end with the directors.^[3]

Conveniently, the dipole parasitic elements have a node (point of zero RF voltage) at their centre, so they can be attached to a conductive metal support at that point without need of insulation, without disturbing their electrical operation.^[4] They are usually bolted or welded to the antenna's central support boom.^[4] The most common form of the driven element is one fed at its centre so its two halves must be insulated where the boom supports them.

The gain increases with the number of parasitic elements used.^[4] Only one reflector is normally used since the improvement of gain with additional reflectors is small, but more reflectors may be employed for other reasons such as wider bandwidth. Yagis have been built with up to 30–40 directors.^[3]

The bandwidth of an antenna is, by one definition, the width of the band of frequencies having a gain within 3 dB (one-half the power) of its maximum gain. The Yagi–Uda array in its basic form has very narrow bandwidth, 2–3 percent of the centre frequency.^[4] There is a tradeoff between gain and bandwidth, with the bandwidth narrowing as more elements are used.^[4] For applications that require wider bandwidths, such as terrestrial television, Yagi–Uda antennas commonly feature trigonal reflectors, and larger diameter conductors, in order to cover the relevant portions of the VHF and UHF bands.^[11] Wider bandwidth can also be achieved by the use of "traps", as described below.

Yagi–Uda antennas used for amateur radio are sometimes designed to operate on multiple bands. These elaborate designs create electrical breaks along each element (both sides) at which point a parallel LC (inductor and capacitor) circuit is inserted. This so-called trap has the effect of truncating the element at the higher frequency band, making it approximately a half wavelength in length. At the lower frequency, the entire element (including the remaining inductance due to the trap) is close to half-wave resonance, implementing a different Yagi–Uda antenna. Using a second set of traps, a "triband" antenna can be resonant at three different bands. Given the associated costs of erecting an antenna and rotator system above a tower, the combination of antennas for three amateur bands in one unit is a very practical solution. The use of traps is not without disadvantages, however, as they reduce the bandwidth of the antenna on the individual bands and reduce the antenna's electrical efficiency and subject the antenna to additional mechanical considerations (wind loading, water and insect ingress).

Consider a Yagi–Uda consisting of a reflector, driven element and a single director as shown here. The driven element is typically a 1⁄2λ dipole or folded dipole and is the only member of the structure that is directly excited (electrically connected to the feedline). All the other elements are considered parasitic. That is, they reradiate power which they receive from the driven element. They also interact with each other, but this mutual coupling is neglected in the following simplified explanation, which applies to far-field conditions.

One way of thinking about the operation of such an antenna is to consider a parasitic element to be a normal dipole element of finite diameter fed at its centre, with a short circuit across its feed point. The principal part of the current in a loaded receiving antenna is distributed as in a center-driven antenna. It is proportional to the effective length of the antenna and is in phase with the incident electric field if the passive dipole is excited exactly at its resonance frequency.^[12] Now we imagine the current as the source of a power wave at the (short-circuited) port of the antenna. As is well known in transmission line theory, a short circuit reflects the incident voltage 180 degrees out of phase. So one could as well model the operation of the parasitic element as the superposition of a dipole element receiving power and sending it down a transmission line to a matched load, and a transmitter sending the same amount of power up the transmission line back toward the antenna element. If the transmitted voltage wave were 180 degrees out of phase with the received wave at that point, the superposition of the two voltage waves would give zero voltage, equivalent to shorting out the dipole at the feedpoint (making it a solid element, as it is). However, the current of the backward wave is in phase with the current of the incident wave. This current drives the reradiation of the (passive) dipole element. At some distance, the reradiated electric field is described by the far-field component of the radiation field of a dipole antenna. Its phase includes the propagation delay (relating to the current) and an additional 90 degrees lagging phase offset. Thus, the reradiated field may be thought as having a 90 degrees lagging phase with respect to the incident field.

Parasitic elements involved in Yagi–Uda antennas are not exactly resonant but are somewhat shorter (or longer) than 1⁄2λ so that the phase of the element's current is modified with respect to its excitation from the driven element. The so-called reflector element, being longer than 1⁄2λ, has an inductive reactance, which means the phase of its current lags the phase of the open-circuit voltage that would be induced by the received field. The phase delay is thus larger than 90 degrees and, if the reflector element is made sufficiently long, the phase delay may be imagined to approach 180 degrees, so that the incident wave and the wave reemitted by the reflector interfere destructively in the forward direction (i.e. looking from the driven element towards the passive element). The director element, on the other hand, being shorter than 1⁄2λ, has a capacitive reactance with the voltage phase lagging that of the current.^[13] The phase delay is thus smaller than 90 degrees and, if the director element is made sufficiently short, the phase delay may be imagined to approach zero and the incident wave and the wave reemitted by the reflector interfere constructively in the forward direction.

Interference also occurs in the backward direction. This interference is influenced by the distance between the driven and the passive element, because the propagation delays of the incident wave (from the driven element to the passive element) and of the reradiated wave (from the passive element back to the driven element) have to be taken into account. To illustrate the effect, we assume zero and 180 degrees phase delay for the reemission of director and reflector, respectively, and assume a distance of a quarter wavelength between the driven and the passive element. Under these conditions the wave reemitted by the director interferes destructively with the wave emitted by the driven element in the backward direction (away from the passive element), and the wave reemitted by the reflector interferes constructively.

In reality, the phase delay of passive dipole elements does not reach the extreme values of zero and 180 degrees. Thus, the elements are given the correct lengths and spacings so that the radio waves radiated by the driven element and those re-radiated by the parasitic elements all arrive at the front of the antenna in-phase, so they superpose and add, increasing signal strength in the forward direction. In other words, the crest of the forward wave from the reflector element reaches the driven element just as the crest of the wave is emitted from that element. These waves reach the first director element just as the crest of the wave is emitted from that element, and so on. The waves in the reverse direction interfere destructively, cancelling out, so the signal strength radiated in the reverse direction is small. Thus the antenna radiates a unidirectional beam of radio waves from the front (director end) of the antenna.

While the above qualitative explanation is useful for understanding how parasitic elements can enhance the driven elements' radiation in one direction at the expense of the other, the assumption of an additional 90 degrees (leading or lagging) phase shift of the reemitted wave is not valid. Typically, the phase shift in the passive element is much smaller. Moreover, to increase the effect of the passive radiators, they should be placed close to the driven element, so that they can collect and reemit a significant part of the primary radiation.

•  

  How the antenna works. The radio waves from each element are emitted with a phase delay, so that the individual waves emitted in the forward direction (up) are in phase, while the waves in the reverse direction are out of phase. Therefore, the forward waves add together, (constructive interference) enhancing the power in that direction, while the backward waves partially cancel each other (destructive interference), thereby reducing the power emitted in that direction.

•  

  Illustration of forward gain of a two element Yagi–Uda array using only a driven element (left) and a director (right). The wave (green) from the driven element excites a current in the passive director which reradiates a wave (blue) having a particular phase shift (see explanation in text, note that the dimensions are not to scale with the numbers in the text). The addition of these waves (bottom) is increased in the forward direction, but leads to partial cancellation in the reverse direction.

A more realistic model of a Yagi–Uda array using just a driven element and a director is illustrated in the accompanying diagram. The wave generated by the driven element (green) propagates in both the forward and reverse directions (as well as other directions, not shown). The director receives that wave slightly delayed in time (amounting to a phase delay of about 45° which will be important for the reverse direction calculations later). Due to the director's shorter length, the current generated in the director is advanced in phase (by about 20°) with respect to the incident field and emits an electromagnetic field, which lags (under far-field conditions) this current by 90°. The net effect is a wave emitted by the director (blue) which is about 70° (20° - 90°) retarded with respect to that from the driven element (green), in this particular design. These waves combine to produce the net forward wave (bottom, right) with an amplitude somewhat larger than the individual waves.

In the reverse direction, on the other hand, the additional delay of the wave from the director (blue) due to the spacing between the two elements (about 45° of phase delay traversed twice) causes it to be about 160° (70° + 2 × 45°) out of phase with the wave from the driven element (green). The net effect of these two waves, when added (bottom, left), is partial cancellation. The combination of the director's position and shorter length has thus obtained a unidirectional rather than the bidirectional response of the driven (half-wave dipole) element alone.

When a passive radiator is placed close (less than a quarter wavelength distance) to the driven dipole, it interacts with the near field, in which the phase-to-distance relation is not governed by propagation delay, as would be the case in the far field. Thus, the amplitude and phase relation between the driven and the passive element cannot be understood with a model of successive collection and reemission of a wave that has become completely disconnected from the primary radiating element. Instead, the two antenna elements form a coupled system, in which, for example, the self-impedance (or radiation resistance) of the driven element is strongly influenced by the passive element. A full analysis of such a system requires computing the mutual impedances between the dipole elements^[14] which implicitly takes into account the propagation delay due to the finite spacing between elements and near-field coupling effects. We model element number j as having a feedpoint at the centre with a voltage V_j and a current I_j flowing into it. Just considering two such elements we can write the voltage at each feedpoint in terms of the currents using the mutual impedances Z_ij:

${\displaystyle V_{1}=Z_{11}I_{1}+Z_{12}I_{2}}$ 

${\displaystyle V_{2}=Z_{21}I_{1}+Z_{22}I_{2}}$ 

Z₁₁ and Z₂₂ are simply the ordinary driving point impedances of a dipole, thus 73 + j43 ohms for a half-wave element (or purely resistive for one slightly shorter, as is usually desired for the driven element). Due to the differences in the elements' lengths Z₁₁ and Z₂₂ have a substantially different reactive component. Due to reciprocity we know that Z₂₁ = Z₁₂. Now the difficult computation is in determining that mutual impedance Z₂₁ which requires a numerical solution. This has been computed for two exact half-wave dipole elements at various spacings in the accompanying graph.

The solution of the system then is as follows. Let the driven element be designated 1 so that V₁ and I₁ are the voltage and current supplied by the transmitter. The parasitic element is designated 2, and since it is shorted at its "feedpoint" we can write that V₂ = 0. Using the above relationships, then, we can solve for I₂ in terms of I₁:

${\displaystyle 0=V_{2}=Z_{21}I_{1}+Z_{22}I_{2}}$ 

and so

${\displaystyle I_{2}=-{Z_{21} \over Z_{22}}\,I_{1}}$ .

This is the current induced in the parasitic element due to the current I₁ in the driven element. We can also solve for the voltage V₁ at the feedpoint of the driven element using the earlier equation:

${\displaystyle {\begin{aligned}V_{1}&=Z_{11}I_{1}+Z_{12}I_{2}=Z_{11}I_{1}-Z_{12}{Z_{21} \over Z_{22}}\,I_{1}\\&=\left(Z_{11}-{Z_{21}^{2} \over Z_{22}}\right)I_{1}\end{aligned}}}$ 

where we have substituted Z₁₂ = Z₂₁. The ratio of voltage to current at this point is the driving point impedance Z_dp of the 2-element Yagi:

${\displaystyle Z_{dp}=V_{1}/I_{1}=Z_{11}-{Z_{21}^{2} \over Z_{22}}}$ 

With only the driven element present the driving point impedance would have simply been Z₁₁, but has now been modified by the presence of the parasitic element. And now knowing the phase (and amplitude) of I₂ in relation to I₁ as computed above allows us to determine the radiation pattern (gain as a function of direction) due to the currents flowing in these two elements. Solution of such an antenna with more than two elements proceeds along the same lines, setting each V_j = 0 for all but the driven element, and solving for the currents in each element (and the voltage V₁ at the feedpoint).^[15] Generally the mutual coupling tends to lower the impedance of the primary radiator and thus, folded dipole antennas are frequently used because of their large radiation resistance, which is reduced to the typical 50 to 75 Ohm range by coupling with the passive elements.

There are no simple formulas for designing Yagi–Uda antennas due to the complex relationships between physical parameters such as

• element length and spacing
• element diameter
• performance characteristics: gain and input impedance

However using the above kinds of iterative analysis, one can calculate the performance of a given a set of parameters and adjust them to optimize the gain (perhaps subject to some constraints). Since with an n element Yagi–Uda antenna, there are 2n − 1 parameters to adjust (the element lengths and relative spacings), this iterative analysis method is not straightforward. The mutual impedances plotted above only apply to λ/2 length elements, so these might need to be recomputed to get good accuracy.

The current distribution along a real antenna element is only approximately given by the usual assumption of a classical standing wave, requiring a solution of Hallen's integral equation taking into account the other conductors. Such a complete exact analysis, considering all of the interactions mentioned, is rather overwhelming, and approximations are inevitable on the path to finding a usable antenna. Consequently, these antennas are often empirical designs using an element of trial and error, often starting with an existing design modified according to one's hunch. The result might be checked by direct measurement or by computer simulation.

A well-known reference employed in the latter approach is a report published by the United States National Bureau of Standards (NBS) (now the National Institute of Standards and Technology (NIST)) that provides six basic designs derived from measurements conducted at 400 MHz and procedures for adapting these designs to other frequencies.^[16] These designs, and those derived from them, are sometimes referred to as "NBS yagis."

By adjusting the distance between the adjacent directors it is possible to reduce the back lobe of the radiation pattern.

The Yagi–Uda antenna was invented in 1926 by Shintaro Uda of Tohoku Imperial University,^[5] Sendai, Japan, with the guidance of Hidetsugu Yagi, also of Tohoku Imperial University.^[6] Yagi and Uda published their first report on the wave projector directional antenna. Yagi demonstrated a proof of concept, but the engineering problems proved to be more onerous than conventional systems.^[17]

Yagi published the first English-language reference on the antenna in a 1928 survey article on short wave research in Japan and it came to be associated with his name. However, Yagi who provided the conception which was originally vague expression to Uda, always acknowledged Uda's principal contribution towards the design which will currently be recognized as the reduction to practice, and if the novelty is not considered, the proper name for the antenna is, as above, the Yagi–Uda antenna (or array).

The Yagi was first widely used during World War II for airborne radar sets, because of its simplicity and directionality.^[17][18] Despite its being invented in Japan, many Japanese radar engineers were unaware of the design until very late in the war, partly due to rivalry between the Army and Navy. The Japanese military authorities first became aware of this technology after the Battle of Singapore when they captured the notes of a British radar technician that mentioned "yagi antenna". Japanese intelligence officers did not even recognise that Yagi was a Japanese name in this context. When questioned, the technician said it was an antenna named after a Japanese professor.^{[19][20][N 1]}

A horizontally polarized array can be seen under the leading edge of Grumman TBF Avenger carrier-based US Navy aircraft and the Consolidated PBY Catalina long range patrol seaplane. Vertically polarized arrays can be seen on the cheeks of the P-61 and on the nose cones of many WWII aircraft, notably the Lichtenstein radar-equipped examples of the German Junkers Ju 88R-1 fighter-bomber, and the British Bristol Beaufighter night-fighter and Short Sunderland flying-boat. Indeed, the latter had so many antenna elements arranged on its back – in addition to its formidable turreted defensive armament in the nose and tail, and atop the hull – it was nicknamed the fliegendes Stachelschwein, or "Flying Porcupine" by German airmen.^[21] The experimental Morgenstern German AI VHF-band radar antenna of 1943–44 used a "double-Yagi" structure from its 90° angled pairs of Yagi antennas formed from six discrete dipole elements, making it possible to fit the array within a conical, rubber-covered plywood radome on an aircraft's nose, with the extreme tips of the Morgenstern's antenna elements protruding from the radome's surface, with an NJG 4 Ju 88G-6 of the wing's staff flight using it late in the war for its Lichtenstein SN-2 AI radar.^[22]

After World War 2, the advent of television broadcasting motivated extensive adaptation of the Yagi–Uda design for rooftop television reception in the VHF band (and later for UHF television) and also as an FM radio antenna in fringe areas. A major drawback was the Yagi's inherently narrow bandwidth, eventually solved by the adoption of the very wideband log-periodic dipole array (LPDA). Yet the Yagi's higher gain compared to the LPDA makes it still required for the best fringe reception, and very complicated Yagi designs and combination with other antenna technologies have been developed to permit its operation over the broad television bands.

The Yagi–Uda antenna was named an IEEE Milestone in 1995.^[10]

• Antenna (radio)
• Antenna array
• Numerical Electromagnetics Code
• Radio direction finder
• Radio direction finding

Citations

Bibliography

• Brown, Louis (1999). A radar history of World War II: technical and military imperatives. CRC Press. ISBN 0-7503-0659-9
• S. Uda, "High angle radiation of short electric waves". Proceedings of the IRE, vol. 15, pp. 377–385, May 1927.
• S. Uda, "Radiotelegraphy and radiotelephony on half-meter waves". Proceedings of the IRE, vol. 18, pp. 1047–1063, June 1930.
• J. E. Brittain, Scanning the Past, Shintaro Uda and the Wave Projector, Proc. IEEE, May 1997, pp. 800–801.
• H .Yagi, Beam transmission of ultra-shortwaves, Proceedings of the IRE, vol. 16, pp. 715–740, June 1928. The URL is to a 1997 IEEE reprint of the classic article. See also Beam Transmission Of Ultra Short Waves: An Introduction To The Classic Paper By H. Yagi by D.M. Pozar, in Proceedings of the IEEE, Volume 85, Issue 11, Nov. 1997 Page(s):1857–1863.
• "Scanning the Past: A History of Electrical Engineering from the Past". Proceedings of the IEEE Vol. 81, No. 6, 1993.
• Shozo Usami and Gentei Sato, "Directive Short Wave Antenna, 1924". IEEE Milestones, IEEE History Center, IEEE, 2005.
• Toma KAWANISHI (7 April 2020). "Conceptualizing engineering as a science: Hidetsugu Yagi as a promoter of engineering research". Philosophy and History of Science Studies. Philosophy and History of Science, Kyoto University. 14 (14): 1–24. doi:10.14989/250442.
• Griffiths, Hugh (1 January 2022). "The Yagi Antenna". IEEE Aerospace and Electronic Systems Magazine. IEEE. 37 (1): 4–5. doi:10.1109/MAES.2021.3127141. S2CID 245708628. Retrieved 12 December 2022.

• Yagi-Uda antenna History". History of antenna invention and its patents.
• D. Jefferies, "Yagi-Uda antennas". 2004.
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• Yagi-Uda Antenna. Simple information on basic design, project and measure of Yagi–Uda antenna. 2008
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