InnovAntennas use the very latest in electromagnetic computer design technology in conjunction withParticle Swarm Optimisation methods (considered to be the best in optimisation technology today) to produce some of the most innovative and high performance antenna solutions available today.
Exclusive designs from some of the world's top antenna designers have been turned into professionally built, mechanically excellent antennas with a focus upon being manufactured the right way not the most cost effective way. A number of variants of each model can be produced in order to cater for the real-world requirements of both the commercial and ham customer. Considerations for light-weight, high wind handling ability, portability and long-term durability mean that no-one mechanical design can deliver a best-of-breed for all scenarios. AtInnovAntennaswe appreciate this fact and aim to deliver the product you want rather than the product that is most profitable for us.
Our antennas are not designed to provide the best 'on-paper' gain figures, instead we design our antennas for the requirements ofthe band in question and for the specific purpose the antenna will be used. For example, on many HF bands, optimising an antenna for maximum gain is the way to go in most cases (but not all) provided a near 50 Ohm impedance can be maintained through its bandwidth. However, on most VHF and all UHF bands, optimising in such a way is detrimental to the receive performance of the antenna and therefore inappropriate for the antenna to be designed this way. This is assuming the antenna needs to receive as well as it does transmit. In many cases, never-achieved-before attributes such as Sky Temperature and G/T Figures are better with InnovAntennasYagis (per metre of boom)*. If you want to be assured of the absolute best performance and antenna stability, along with design consideration for your intended use, InnovAntennas are your only option.
PERFECTLY CENTRED ELEMENTS, COAX EXIT ROTATION AND NON-METALLIC H-FRAMES
If you want an X-pol Yagi and wish to maintain the software predicted noise figures (G/T) the ONLYway this can be achieved is with perfectly centres X and Y planes. If the elements in each plane are off-set or even have a matching section (such as a T-match) extend into the opposing plane, pattern distortion and noise figure degradation WILL occur. It does not matter what you read or see if noise figures on paper, those models did not include the off-set!
Some customers take the advice and do things right, Constantin, KG6NK is one of those guys. We built his 4 x 22el 144MHz low noise LFA Yagis with perfectly centred, thru-boom elements and he built an H-frame to support the system completely from fibre glass. Simply adding a small piece of fibreglass to the ends of metallic supports does not cut it, the remainder of the metallic tube WILL conduct and WILL degradation performance. Constantin had excellent results with his 2 x 22el built this way so decided to upgrade to 4 and the installation is almost done!
Almost there! a 4 x 22el X-pol low noise LFA Yagi system with perfectly centred elements with just cables to connect, at KG6NK
All coax cables, when completed will exit the rear of the antennas and the forward-most coax cable / ferrite choke is curved and has a rotational exit from the feed point in order there are no, flat surfaces (coax cable is metallic too!) in order to minimise any potential interaction.
When investing in VHF/UHF systems for low noise applications, particularly EME, it is important to do it right, not what best works for mass production purposes. Ensure you get antennas manufactures the best way to ensure excellent results. If this sounds like the way you want to have your EME system configured, let us know and InnovAntennas and we will give you all the help and advise you need, post and pre-sale.
X-pol Configuration Check List:
• Perfectly centred elements with no off-set (particularly important on 70cms)
• Absolute minimal contact with any element (no feed point boxes or structures)
• Rotational exit of coax/balun from the feed point
• Rear exit of all coax cables
• Rear Splitter mount to hold splitter rearward for minimal coaxial runs (in photo)
• Non-metallic H-frame
Of you want the best in low noise Yagi replication – look no further than InnovAntennas
Photo: Almost there! - Constantin sent us this photo of his system almost ready to go. Next step, cable connections and finalisation!
ADVANCEMENT THROUGH ELIMINATION: WHY REMOVING THE FEED POINT BOX MATTERS
The intricacies of VHF/UHF Yagi antenna design are notably influenced by real-world implementation choices, with the feed point box playing a pivotal but negative role. Many software models overlook this component, leading to predictions that are not a true representation of what the end-user experiences. Not only does it retain moisture over time, but its presence also distorts the antenna pattern, influences the noise figure, and ultimately degrades the G/T performance. This degradation contrasts sharply with the model's predictions if the feed point box was omitted. The only discernible benefit of the box is aesthetic, making the Yagi appear more polished.
InnovAntennas confronts these challenges head-on. We prioritise the use of RF-friendly materials and design with minimal supporting structures. We avoid feed point boxes entirely, sidestepping their associated problems. Instead, we employ a direct connection using small, durable user-serviceable connections. This ensures longevity. Additionally, it offers users easy maintenance without the need for proprietary parts from InnovAntennas. Our Yagis strike a harmonious balance between the perfection of a software model and the practicalities of real-world construction, delivering industry-leading performance by setting new standards in real-world model replication.
For those who aim for the apex of low-noise performance, with a steadfast commitment to design integrity and longevity, the low noise LFA Yagi stands unmatched. we've completely eliminated the traditional feed point box, commonly susceptible to moisture retention and the ensuing performance deterioration. This deliberate engineering choice ensures a moisture-free, low-loss, low noise connection - a feature notably absent across the industry and one that ensures our G/T results are closer to predicted noise figures than anyone else. Our approach safeguards against the common pitfalls of water ingress, which can lead to tuning fluctuations and potential transceiver damage from impedance discrepancies. The LFA Yagi offers a universal pillar of dependability and superior performance in any environment, catering to those who prioritise peak performance without compromise.
4 x 20el 144MHz low noise LFA Yagis at FM5CS - Perfectly centred elements and absolute minimal supporting structures around the antenna to ensure modelled pattern replication.
THE LFA YAGI'S FEED POINT: UNCOVERED
For enthusiasts seeking unrivalled low-noise performance, the low noise LFA Yagi from InnovAntennas stands as a paragon of excellence. Our innovative design approach centres on more than just avoiding moisture; it vitally focuses on preventing the detrimental shrouding of the dipole, the Yagi's most vital component. Conventional feed point boxes, commonly found in traditional designs, cover a significant part of the dipole's centre, inadvertently inducing noise and degrading both the noise figure and the G/T performance. Discarding this standard approach, the LFA Yagi delivers an unobstructed, low noise experience, ensuring that the antenna's real-world performance closely mirrors the optimised theoretical models. This dedication to design integrity propels the LFA Yagi beyond conventional limitations, offering an experience unparalleled for the discerning operator.
To the novice, the driven element of the LFA Yagi might seem like just another folded dipole. However, this assumption is far from reality. In this piece, we will explore in depth the reasons why the low noise LFA truly stands apart from the crowd.
Beyond its distinctive rectangular loop, surrounded by parasitic elements, the LFA Yagi's true uniqueness stems from the additional control parameters incorporated during the optimisation process. These intricacies significantly bolster the Yagi's performance, enhancing its noise reduction, gain, Front to Back Ratio (F/B), and bandwidth attributes. Following this introduction, we'll delve into a detailed breakdown of its key features.
4 x 10el low noise 50MHz LFA Yagis on 17.7m long booms at KJ9I
Below is a list of key features which shall be elaborated on further within this piece.
Low noise Yagi – ‘The Urban’ or City Yagi
Distinctive Close loop driven element
Optimised performance with direct 50Ω feed
Extended bandwidth capabilities of the LFA
Closed Loop Impedance - explained
Driven element with DC ground
Lower native impedance
Self-Balancing Yagi
Symmetrical in both AZ/EL
Band Pass Filter properties of the LFA
Higher power handling
Phased Loop cancellation properties
Enhanced Optimisation Dynamics of the LFA
Best-in-class G/T
Evolution of Computer Optimisation and the LFA’s place in it
Real World Translation of the Perfect Antenna Model
Future-Proofing the X-pol Yagi: Centralised elements & Cable Integration
The Low Noise LFA Yagi – The Optimal Choice for Noise-Laden Urban Areas
Before we look deeper into the specifics, let's set the scene with a tangible demonstration of its real-world performance. A Canadian ham, equipped with a 7-element 50MHz Yagi from a distinguished USA-based brand, chose to transition to a low noise LFA, maintaining both the length and the number of elements. With the new LFA proudly perched on a fresh tower, plans were set in motion to retire the older 7-element American model in favour of an HF multi-bander.
However, prior to the final switch, he was driven by curiosity. Engaging in A/B tests, he connected both antennas to distinct sockets on the same radio. In the comparison video provided below, you'll observe that while the signal strengths might appear similar, the low noise LFA's remarkable reduction in the noise floor transforms barely perceptible signals from the original 7-element antenna into crisp Q5 signals.
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So, what magic does the low noise LFA Yagi weave to stand out in its performance?
The Distinctive Closed Loop Driven Element of the LFA The low noise LFA Yagi's signature closed, rectangular loop driven element is a marvel of engineering adaptability. Unlike the static nature of traditional dipoles, the LFA's loop thrives in a three-dimensional space, granting it unparalleled flexibility of adjustment.
Here's where it stands apart: In traditional Yagi optimisation, when the dipole shifts, it either approaches the reflector while distancing from the director or vice versa. However, the LFA's loop, with its unique three-dimensional construct, doesn't abide by this limitation. It can expand or contract along the boom, allowing it to adjust its distance from both the reflector and the director simultaneously. This means it can move closer to both, further from both, or selectively change its distance to only one of them whilst keeping its relationship with the other constant.
Furthermore, the choice of the loop's feed point placement—be it nearer to the reflector or the director—introduces another dimension of optimisation. Each placement brings forth distinct performance characteristics, which are then meticulously refined through subsequent optimisation.
It's this multifaceted adjustability, combined with detailed computer optimisation, that sets the LFA loop apart from any other Yagi, making it a beacon of innovation in Yagi design.
Optimised Performance with a Direct-Fed 50Ω LFA Yagi
Traditional dipole-fed Yagis operating at 50Ω impedance often deliver average performance. Enhancements in performance can be achieved by reducing the feed point impedance. However, this brings about its own challenges. While the lower impedance can bolster performance metrics like forward gain and F/B, it also necessitates the integration of a transformer or matching device to restore the feed impedance to the standard 50Ω. This adaptation leads to inefficiencies, possibly negating the advantages of the lowered impedance. This is where the low noise LFA Yagi, with its unique loop design, truly shines. The LFA offers the enhanced performance characteristics typical of a traditional split-dipole Yagi with lowered impedance, yet it maintains a direct 50Ω feed, eliminating the need for additional matching devices. This combination ensures optimum performance without the associated losses of traditional designs.
4 x 7el 50MHz & 2 x 18el 144MHz low noise LFA Yagis at K1USA
Expansive Bandwidth with the LFA – No Compromises on Performance
The LFA Yagi has made waves in the world of Ham Radio, particularly when it comes to bandwidth capabilities. Traditional beliefs held that native low impedance Yagis would inherently have a reduced bandwidth. Yet, the LFA Yagi, with its unique three-dimensional loop adjustments, has showcased that it's possible to maintain, and even increase, bandwidth without compromising on other performance metrics.
This is notably evident when comparing the LFA Yagi to the benchmark Optimised Wideband Array (OWA) Yagi. The OWA, with its two-dimensional split dipole, has been lauded for its expansive bandwidth. However, the LFA's ability to adjust its loop depth—either uniformly or selectively on one side—and to switch its feed point position between the back or front, gives it an edge in optimisation. This results in a Yagi that not only rivals the bandwidth of the OWA but sometimes even surpasses it, all the while delivering higher levels of performance.
Closed-Loop Impedance Explained
A standalone loop, without being part of a Yagi, typically has an impedance ranging between 200Ω and 300Ω, which varies based on the rectangle's shape. When you introduce parasitic elements, such as reflectors and directors, to flank this rectangle, the feed impedance of the loop decreases. Factors influencing this final impedance include the number, shape, length, and proximity of these additional elements to the rectangle.
This is where intricate optimisation comes into play to attain the remarkable results we see with the low noise LFA Yagi. As computational capabilities advance and speeds increase, the LFA Yagi, too, continues to evolve and improve.
It's essential to clarify that while G0KSC offers free-to-build LFA designs on his website, these represent his initial creations from more than 14 years ago. In contrast, only InnovAntennas provide the latest and most refined antenna designs by G0KSC, including the superior next-generation low noise LFA Yagi.
By meticulously optimising a Yagi antenna with an LFA loop, we've achieved a remarkable feat: bringing the impedance down to an ideal 50Ω without need for any matching device. This optimisation isn't just about hitting the right numbers; it's about harnessing the full potential of the antenna's performance and bandwidth.
In a typical scenario with split dipole Yagis, the initial impedance starts at around 70Ω. But through the process of optimisation, this impedance can drop significantly, often falling between 10Ω and 30Ω. Such a reduction necessitates the use of a matching device, adding complexity and inefficiencies to the system.
The LFA Yagi stands in stark contrast to this. Its unique loop design allows it to maintain a direct 50Ω feed, bypassing the need for additional matching devices. This direct feed not only simplifies the overall design but also ensures optimum performance without the losses often associated with traditional designs.
In the past, there were efforts to optimise Yagis with split dipoles to achieve a final impedance of 200Ω. Some experimented with replacing the split dipole with a traditional compact folded dipole, which naturally transformed the impedance to around 50Ω. While this approach did improve bandwidth over a similar length 50Ω split dipole Yagi, it adversely affected essential performance metrics like Gain and F/B ratio. Consequently, this design method was not widely adopted.
4 x 7el 50MHz low noise LFA WOS Yagis at US0KW
DC Ground – Enhancing Performance and Safety
At the core of the LFA loop system's design is its DC ground connection, astutely positioned opposite the feed point. This strategic design choice is pivotal in optimising the antenna's functionality. The ground connection, situated at a zero current point at the operating frequency, performs a dual function. It helps ensure effective radiation of all RF energy up to this juncture, leaving only voltage which in turn helps prevent common-mode currents travelling back along the feedline. Therefore, this feature also contributes to balancing the feed point, akin to the feed point balancing function of a ¼ wavelength hairpin which is extremely important within a Yagi if gain and F/B are to be maintained as model.
The Self-Balancing Yagi
This approach to grounding goes beyond a simple design choice; it is a vital enhancement that significantly betters the Yagi's symmetrical performance. Such a grounding technique, unique to a loop-fed design, delivers benefits that are unattainable with traditional split-dipole designs. Moreover, the ground connection plays a vital role in safeguarding transceiver equipment from static electrical damage.
A 432MHz X-pol LFA Yagi showcasing perfectly centred elements and no feed point boxes, essential for accurate software pattern model replication.
Symmetrical in both AZ/EL
An additional advantage of the LFA loop system is its uniform alignment with all parasitic elements. This alignment ensures perfectly symmetrical elevation (EL) lobes, an attribute elusive in traditional folded dipole Yagis. In conventional designs, where the folded dipole sides are positioned above and below the boom, elevation lobes tend to be asymmetrical. This distortion in lobes becomes increasingly pronounced at higher frequencies, and these complexities are compounded within X-pol designs. The LFA Yagi, with its forward-thinking design, overcomes such challenges and ensures a distortion-free 3-dimensional pattern.
Optimised Band Pass Filter (BPF) for Enhanced Noise Control Building on the unique attributes of the LFA Yagi, it's important to note the sophisticated implementation of a Band Pass Filter (BPF). This feature is intricately linked to the DC ground, which is effectively invisible at the antenna's design frequency. As the frequency deviates from this set point, there's a significant increase in impedance. This deliberate design choice not only results in the BPF effect, adeptly minimising noise outside the designated band but also leads into the broader scope of benefits encompassed in the LFA Yagi's design.
This BPF property extends its benefits beyond transmission, where it plays an important role in reducing the risk of causing interference. It also acts as a vital safeguard during reception, significantly lowering the likelihood of receiving interference from out-of-band sources or high-powered transmitters. This characteristic is particularly important in bands like 50MHz, especially in regions where older, powerful TV transmitters operate adjacent to the ham radio band. The integration of this BPF feature into the LFA Yagi enhances both transmission quality and reception ability, making it an indispensable asset for operators across various environments.
4 x 22el X-pol low noise LFA Yagis for 144MHz at W6TCP. All element perfectly centred mid-boom - the only way to ensure pattern symmetry and avoid pattern distortion and G/T loss
High Power (QRO)? No Problem!
Historically, the cubical quad was designed to facilitate very high-power transmissions, especially at elevated altitudes where the air is less dense. In such conditions, transmitting high power to split dipole Yagi antennas could lead to coronal discharge from the element tips – a sparking effect. This could cause the tips to melt, resulting in the breakdown of the driven element and potential damage to transmitters.
However, the low noise LFA stands distinct. While oriented differently compared to the typical quad beam, the LFA's loop is a full-wave loop, comparable to those used in quad beams. Its closed-loop design eliminates the issue of melting tips, enabling it to handle much higher power levels. In fact, certain commercial LFA Yagi variants can manage powers in the tens of kilowatts at specific frequencies.
Phase Cancellation in the Driven Loop – Minimised Side Lobes
An essential feature, harnessed during the computer optimisation phase, is the flat end sections of the LFA Loop that sit parallel to each other on either side of the boom. A combination of the final rectangle shape of the LFA loop, coupled with the number and proximity of parasitic elements, can result in these loop ends being 180 degrees out of phase. This phase cancellation effect subsequently leads to pronounced Front to Side (F/S) nulls. As a result, any potential unwanted forward-facing side lobes are significantly suppressed, ensuring a more distinct, singular forward lobe. Furthermore, this effect can also substantially enhance the F/B capabilities.
With side lobes either minimised or eradicated, the low noise LFA becomes an optimal choice for ultra-low noise applications or precise point-to-point transmissions. This standout feature is a prime reason the low noise LFA has been chosen for specific defence applications.
Beyond the Basics: The Enhanced Optimisation Dynamics of the Driven Loop
Within the realm of computer optimisation software for Yagi design, standard parameters like element position on the boom and element length are typically manipulated to achieve an optimised Yagi. This software offers precise pattern and performance simulation tools, facilitating a real-world preview of each design iteration. It continually adjusts element sets, both collectively and individually, modifying their positions and lengths. After each adjustment, it evaluates the results, retaining improvements and continually refining.
However, the low noise LFA's driven loop introduces a groundbreaking dimension to this process. Unlike traditional driven elements, the LFA loop's shape and orientation offer an unprecedented level of flexibility in optimisation. Beyond the standard adjustments of moving the entire shape along the boom or altering its width, the loop's depth along the boom can also be modified, unveiling a third dimension of optimisation possibilities.
To illustrate, consider the limitations of adjusting a standard split dipole between the reflector and first director. Moving the dipole closer to the reflector simultaneously distances it from the director, which might present both advantages and disadvantages. In stark contrast, the LFA Loop's design permits simultaneous, independent adjustments to BOTH sides of the loop. It can be configured to approach both the reflector and the director concurrently. Alternatively, the distance between the reflector and the loop might remain constant, while only the spacing between the loop and the director is adjusted. Additionally, the loop can be manipulated so that it distances itself from both the reflector and the director simultaneously. This unparalleled adaptability facilitates enhanced performance in noise reduction, bandwidth, and gain, setting the low noise LFA Yagi apart from other antenna designs.
8 x 18el 144MHz low noise X-pol LFAs at OH2BC - the LFA remains operations in wet weather and even covered in snow - unlike many competative products
Best in Class G/T Performance
G/T (Gain over Temperature) is a mean opinion score created by taking the antenna's forward gain figure and comparing it against the level of noise the antenna receives, measured in degrees Kelvin (K). The lower the figure, the better the performance. This score offers an insight into the antenna's ability to receive weak signals at an antenna elevation angle of 30 degrees.
The Evolution of Yagi Antenna Design and the LFA Yagi's Place in It
The modern age of Yagi design has been shaped significantly by the introduction and evolution of computer modelling software. Early software versions, specifically those reliant on NEC-2, NEC-4.2 and MiniNEC engines, had limitations in their ability to accurately model complex driven element shapes, such as the LFA loop, Quad, and Delta loops and more so, matching devices. This often led to the omission of vital components, like matching devices, from certain Yagi types in the software models. As a result, the performance predicted for these Yagis in software models was overly optimistic since the real-world addition of matching devices introduced losses not accounted for in the software model.
Lionel's, VE7BQH, comprehensive list offers a comparative analysis of Yagis ranging from 50MHz to 430MHz. Despite being populated predominantly with antennas designed in earlier software versions, LFA Yagis from previous generations are notable inclusions. It's testament to their enduring quality that even these earlier LFA models exhibit best-in-class performance when set against other, even newer Yagis on the list.
However, this list doesn't showcase the most recent, improved versions of low noise LFA Yagis. These modern iterations are crafted using sophisticated software packages beyond the scope of Lionel's list, which only accepts antennas designed using the NEC-2 or NEC-4.2 calculation engines. These cutting-edge LFA Yagis employ advanced software that accounts accurately for various real-world influences, such as booms, insulators, and even the effects of the coax cable and baluns.
While the LFA Yagi's unique loop shape eliminates the need for any matching devices, older designs, particularly those modelled in previous software versions, often incorporated such devices post-model, leading to discrepancies between model predictions and real-world performance. The LFA Yagi's design, enabled by the capabilities of modern software, results in a direct 50 Ohm impedance without necessitating external matching devices. As a result, the LFA Yagi can proudly boast its real-world performance figures, as the software model predictions accurately represent the built antenna's capabilities, unimpeded by the addition of post-model matching devices.
Future-Proofing the X-pol Yagi: Centralised elements & Cable Integration
Recent iterations of the low noise LFA Yagi antennas have been meticulously designed for flawless integration into X-pol or Crossed Yagi configurations. Traditional X-pol Yagis often grapple with pattern distortion and diminished G/T figures when transitioning from software models to real-world antennas. This issue is primarily due to the mechanical structure of the dipole or matching device extending beyond the typical two-dimensional plane. Such distortion is exacerbated in designs featuring 'above boom' mounted elements, where each plane of elements intrudes into the EH (Electromagnetic Field) field of the other.
This concern is further compounded when a feed point box is added. Not only does the box itself cause distortion, but it also introduces at least one additional point of connection in the feed line, leading to loss and potential unwanted impedance transformation. In scenarios where connectors are 'open' on one side, this can lead to RF leakage and further loss. InnovAntennas addresses this by minimising connections within the feed line. By removing the feed point box, a direct coaxial line connects the feed point to a low noise Masthead amplifier (LNA), typically used in low noise systems. This approach eliminates unnecessary impedance transformations and ensures a low-loss, direct connection.
The integration of an additional, vertically polarised Yagi in traditional systems to create the ‘X-pol’ can further complicate pattern maintenance due to third-dimensional intrusions. The LFA Yagi, with its innovative design, maintains the perfect alignment and centrality of both horizontal and vertical elements within two planes, in addition to perfect alignment with the feed point, ensures preservation of the antenna's pre-X-pol performance in terms of Gain, Pattern, and G/T.
In sharp contrast, the low noise LFA Yagi's design maintains all elements, feed point, and loop strictly within two planes. This adherence to a streamlined design not only ensures consistent performance but also means that the antenna's noise figure and G/T results are true reflections of theoretical models and empirical measurements. The result is a Yagi antenna that excels in both X-pol and traditional configurations, offering unmatched reliability and performance.
8 x 14el 50MHz low noise LFA WOS Yagis at OH2BC - A monster system with each antenna boom 11m long. We advise on the correct way to install mutli-antenna systems to ensure best results.
Real-World Translation of the Perfect Yagi Model
In the world of Yagi design, the ideal Yagi would appear as close to its software model as possible, suspended in free space without any form of support, and its driven element receiving RF without the need for coaxial cable. However, the reality of construction demands a more pragmatic approach. The challenge is to bridge the gap between the ideal and the tangible without compromising performance.
Element support is non-negotiable in real-world scenarios. A boom is essential for aligning and supporting the elements. Minimalist construction methods, keeping contact with the elements as brief as possible and centred, are paramount. The farther this contact extends along the element's length, the more pronounced its negative influence becomes.
Advancement Through Elimination: Why Removing the Feed Point Box Matters
The intricacies of VHF/UHF Yagi antenna design are notably influenced by real-world implementation choices, with the feed point box playing a pivotal but negative role. Many software models overlook this component, leading to predictions that are not a true representation of what the end-user experiences. Not only does it retain moisture over time, but its presence also distorts the antenna pattern, influences the noise figure, and ultimately degrades the G/T performance. This degradation contrasts sharply with the model's predictions if the feed point box was omitted. The only discernible benefit of the box is aesthetic, making the Yagi appear more polished.
InnovAntennas confronts these challenges head-on. We prioritise the use of RF-friendly materials and design with minimal supporting structures. We avoid feed point boxes entirely, sidestepping their associated problems. Instead, we employ a direct connection using small, durable user-serviceable connections. This ensures longevity. Additionally, it offers users easy maintenance without the need for proprietary parts from InnovAntennas. Our Yagis strike a harmonious balance between the perfection of a software model and the practicalities of real-world construction, delivering industry-leading performance by setting new standards in real-world model replication.
For those who aim for the apex of low-noise performance, with a steadfast commitment to design integrity and longevity, the low noise LFA Yagi stands unmatched. we've completely eliminated the traditional feed point box, commonly susceptible to moisture retention and the ensuing performance deterioration. This deliberate engineering choice ensures a moisture-free, low-loss, low noise connection - a feature notably absent across the industry and one that ensures our G/T results are closer to predicted noise figures than anyone else. Our approach safeguards against the common pitfalls of water ingress, which can lead to tuning fluctuations and potential transceiver damage from impedance discrepancies. The LFA Yagi offers a universal pillar of dependability and superior performance in any environment, catering to those who prioritise peak performance without compromise.
4 x 20el 144MHz low noise LFA Yagis at FM5CS - Perfectly centred elements and absolute minimal supporting structures around the antenna to ensure modelled pattern replication.
The LFA Yagi's Feed Point: Uncovered
For enthusiasts seeking unrivalled low-noise performance, the low noise LFA Yagi from InnovAntennas stands as a paragon of excellence. Our innovative design approach centres on more than just avoiding moisture; it vitally focuses on preventing the detrimental shrouding of the dipole, the Yagi's most vital component. Conventional feed point boxes, commonly found in traditional designs, cover a significant part of the dipole's centre, inadvertently inducing noise and degrading both the noise figure and the G/T performance. Discarding this standard approach, the LFA Yagi delivers an unobstructed, low noise experience, ensuring that the antenna's real-world performance closely mirrors the optimised theoretical models. This dedication to design integrity propels the LFA Yagi beyond conventional limitations, offering an experience unparalleled for the discerning operator.
Conclusion
In the realm of high-performance Yagi antennas, the low noise LFA Yagi stands as an unparalleled masterpiece of engineering ingenuity, meticulously crafted to surpass all conventional limitations and redefine the pinnacle of Yagi design. Its transformative features, encompassing a unique closed-loop driven element, three-dimensional optimisation, direct 50Ω feed, and an innovative DC ground connection, have propelled the LFA Yagi to the forefront of Yagi technology.
The LFA Yagi's closed-loop driven element, a hallmark of its revolutionary design, shatters the constraints imposed by traditional dipoles, offering unprecedented flexibility and optimisation capabilities. This unique loop, unlike its linear counterparts, boasts a three-dimensional design, enabling intricate adjustments along its length, width, and depth. This unparalleled manoeuvrability allows for meticulous fine-tuning of the antenna's performance, tailoring it to specific frequencies and environments with unparalleled precision.
The LFA Yagi's three-dimensional optimization goes beyond the physical realm, extending into the heart of its design process. Unlike traditional Yagis, which rely on two-dimensional optimisation, the LFA Yagi harnesses the power of sophisticated computer software to optimize the antenna's performance in a three-dimensional space. This comprehensive approach ensures that every aspect of the antenna, from its driven element to its parasitic elements, is perfectly aligned and optimized to deliver maximum performance.
The LFA Yagi's 50Ω feed eliminates the need for matching devices, a significant benefit that simplifies the antenna installation and minimizes losses. This innovative feature is a direct result of the closed-loop driven element, which naturally brings the impedance back to 50Ω.
The LFA Yagi's DC ground connection, a testament to its innovative spirit, further enhances the antenna's performance and safety. Unlike traditional Yagis, which typically rely on a feed point box, the LFA Yagi employs a direct DC ground connection, ensuring that the antenna's ground plane remains undisturbed, minimizing noise and maximising performance.
The LFA Yagi's symmetrical elevation lobes and Band Pass Filter (BPF) property ensure optimal signal reception in a wide range of environments. The symmetrical elevation lobes, a direct result of the three-dimensional optimization process, ensure that the antenna's pattern remains consistent regardless of the polarization, providing a consistent performance across all axes. The BPF property, a consequence of the antenna's DC grounding, further enhances signal reception by minimizing interference from out-of-band signals.
In addition to its unparalleled performance, the LFA Yagi boasts exceptional versatility. It can be seamlessly integrated into a wide range of applications, from traditional Yagi configurations to X-pol arrays, making it the ideal choice for any ham radio operator seeking unmatched performance and adaptability.
The low noise LFA Yagi, a culmination of groundbreaking engineering innovations, stands as a testament to the power of human ingenuity. It is the epitome of high-performance Yagi design, surpassing all conventional limitations and redefining the standard of Yagi performance for years to come. For those seeking the ultimate in Yagi performance and reliability, the low noise LFA Yagi is the only choice.
Choose the path of InnovAntennas, where the journey transcends the ordinary, and where additional losses are obsolete and optimal performance is the norm.
Ready to elevate your experience with a low noise LFA Yagi but can't find the perfect fit? We're here to help. Contact us with your specific requirements, and let's work together to craft a bespoke Yagi antenna that sets a new standard in design and performance, tailored just for you. This email address is being protected from spambots. You need JavaScript enabled to view it.
6 x 7el 50MHz low noise LFA Yagis at W7EW vertically stacked on a 200' fully rotatable tower.
4 x 8el 50MHz low noise LFA Yagis at N0TB being redied for EME operation.
It is not just VHF operators that can benefit from the low noise properties of the LFA Yagi - they provide exceptional performance on HF too as does this 21MHz example above
If this is a question you have been asking yourself, you are not alone. Hopefully the following few paragraphs that I have compiled will go a long way answering this.
Understanding the Benefits of a Choke Balun for Your Antenna Setup
What is a Choke Balun?
A choke balun is a device that controls common mode currents in a antennas fed with coax cable, preventing the feed line from becoming part of the antenna.
It is designed to “divorce” the antenna from the feed line, ensuring all power is delivered to the radiator (antenna) itself.
A choke balun is essential when using coaxial cable as the feed line, as it helps to balance the RF signal.
It should be installed at the antenna feed to ensure the antenna remains in balance in addition to reducing RFI ( Radio Frequency Interference) due to coax radiation. installing a second choke at the shack end of the coax will further reduce any remaining common mode currents.
Benefits and Applications
A choke balun reduces RFI into the shack by controlling common mode currents flowing on the outside of the coax shield.
It helps to balance the RF signal, ensuring that all power is delivered to the driven element.
A choke balun can be used to create an air choke, which can be effective over several MHz. However, for multiband and wide band applications, a ferrite core balun (current balun) would be the better option. Dependant on the ferrite material used, performance can be delivered over many hundreds of MHz.
A current balun can be used in conjunction with an ugly balun (air wound coil made of the coax feed line) to further improve antenna performance.
If I need a Balun what type is needed on my antenna?
An InnovAntennas Ferrite Core Balun (Current Balun) installed on a vertical antenna
The article discusses 1:1 current and choke type baluns and does not refer to impedance transforming baluns at all. all InnovAntennas Yagis have a direct 50Ω feed point and thus any 1:1 balun (choke or current balun) can be used.
2 typical 1:1 ferrite core baluns supplied by InnovAntennas
If you do not want to read through the following discussion of baluns and would simply like to buy one to suit the needs of your operation and antennas, follow this link HERE and you will be able to purchase one. we provide the perfect balun for all of our antennas, if you need to contact us about the correct balun for any other antenna, contact us here and ask your questions.
Impedance transforming baluns explained
50 Ohm (Ω) direct feed antennas need a 1:1 balanced to unbalance transformer. However, other antennas need transforming from 12.5Ω to 50Ω up to (and beyond) or 200Ω to 50Ω for example and these types need the impedance to be transformed in addition to the feed point balancing effect. InnovAntennas products are designed without the need for any impedance matching as matching devices can install loss and noise into the antenna system, this is one reason our antennas work so well! You will need a 1:1 balun or choke at the feed point of a Yagi to ensure pattern symmetry and best long term results but why is this needed?
Coax Cable - The unbalanced feeder
Coax is a wonderful product. It’s invention has allowed the feeding of antennas through a manner of different substances, conditions and places a balanced feed line could not. However, there are issues that need to be overcome when feeding a balanced antenna with coax.
Radio hams and commercial users often prefer coax to feed antennas due to its convenience. Modern transceivers typically have an unbalanced output designed for direct coax cable connections. Coax can be routed through walls, underground, or up towers and metal poles without significantly affecting the antenna or its tuning. However, it is crucial to avoid overtightening cable ties during installation, as this can alter impedance at specific points. Ensuring a balanced feeder with a choke balun at the antenna feed point is essential to prevent common mode currents from affecting performance. This good practice helps maintain optimal Yagi performance and reduces noise in the antenna system.
Coax Cable or balanced line feeder?
The best way to feed most antennas is with a balanced feeder. The reason being, most antennas (including Yagis which are of interest to us here) are balanced antennas. If we feed a balanced antenna with an unbalanced feed line (coax cable) , issues occur at the feed point; namely common mode currents which appear as a result of this balanced/unbalanced mismatch. These common mode currents travel back down the coax and radiate and thus, the coax becomes a part of our antenna system and radiates. in turn there is less 'illumination' in the driven element and thus gain and performance of the Yagi can drop.
In instances where we are feeding a multi-band vertical or horizontal wire, it may not matter too much to the operator as long as he is radiating a signal from his antenna (despite that there is more likelihood that he will cause interference and have RF in the radio shack due to the coax being a part of the radiating antenna). However, when we are feeding a Yagi, we need to ensure only the antenna itself radiates. Having the coax feeding our Yagi radiating will act to distort the radiation pattern of the antenna. No, this problem will not cause a high SWR. In fact, it may even reduce the SWR seen in the shack giving the ham a false sense of security that things are OK when they are not.
Coiled or 'air-spaced' chokes are relatively narrow band. The InnovAntennas Ferrite Core Balun, a Current balun covers arodun 100MHz and thus is perfectly suited for our range of wide band BOLPA Log Periodic Arrays. the photo shows our Ferrite Core Balun installed upon a BOLPA-10
Balanced line feeders
The most common balanced line feeder in Ham Radio today is the 300Ω ribbon used within the very common G5RV antenna. Any twin line can be used as a balanced line feeder; speaker wire, bell wire, even mains flex. They will all have different characteristics but will all provide a balanced feed to an antenna if used that way. The twin feeder will not radiate (or very little anyway) as a result of the phase of the RF in each feed line being 180 degrees out of phase in each leg. This means, one side of the feed line cancels the other out so no radiation occurs.
Disadvantages of a balanced line
Firstly, we will need a balun to use a balanced line feeder or balanced antenna in any case as radios today are not presenting a balanced output. The next point is the effect that any close by objects have on the balanced feed line, walls, buildings in general, towers, all metal objects, ground, everything! We need the feed line to be in as much open space as possible in order to ensure the balanced feed line can perform as it should. Beginning to understand why a balanced feed is not in mainstream use for the Ham?
We will not go any further into balanced line theory here as the majority of users will be using coax cable although we will look at the consequences of not having a balun installed below.
The Dipole Centre
The dipole is an important part of the Yagi, anything that goes on (or wrong) here is reflected throughout the rest of the Yagi. Below are 2 images of a dipole (fed element) removed from a Yagi. The cross section at the top represents the dipole itself (with green dots along it) while the down-wire is a representation of the coax or balance line feeding the Yagi. The pink lines indicate current distribution within these ‘elements’. Let’s first take a look at fig 1.
Fig1 - perfect symmetry through the dipole
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Fig1. A dipole with a balanced feed
Within Fig1 we can see a nice, clean and balanced distribution of current through the dipole itself with no radiation within the feed line. This represents a scenario where a perfect balun is placed at the feed point or the antenna is fed with a balanced line feeder.
Fig2. A different story if the feed point is not balanced
Fig2 shows the distortion within the dipole if coax is connected and a balun is not installed. This may not impact vertical or mono-pole antennas so much but for a directional antenna such as a Yagi, this is disastrous! Ensure you have a good balun at the feed point of your Yagi to ensure your antenna pattern stays clean, symmetrical and you see the performance you deserve.
Fig2 - No balun installed, coax radiation results in distorted and lower currnet distribution through the dipole
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The balun - What does it do?
In this instance we are discussing 1:1 baluns or chokes which take an unbalanced input from your coax line and allow connection to a balanced antenna feed point. Have you wondered where the name balun comes from? Balanced to Unbalance, that’s it.
By ensuring that the signal is properly matched between the antenna and the feed line, a balun helps to reduce radio frequency interference (RFI) and enhances the overall performance of your antenna system, keeping all your power within the driven element (or dipole), ensures the Yagi can deliver maximum performance. It is good practice to utilise a balun at the junction of balanced and unbalanced feeders to minimise losses and ensure optimal setups.
What is a Balun?
A balun (balanced-to-unbalanced) is a crucial device in antenna systems, particularly for ham radio enthusiasts. It serves the essential function of converting a balanced signal to an unbalanced signal, or vice versa. This conversion is vital for preventing common mode currents from flowing on the coaxial cable, which can lead to unwanted interference and signal degradation. The center conductor plays a significant role in connecting the coaxial cable to the antenna, facilitating proper signal transmission and grounding. By ensuring that the signal is properly matched between the antenna and the feed line, a balun helps to reduce radio frequency interference (RFI) and enhances the overall performance of your antenna system. Whether you’re dealing with a simple dipole or a complex Yagi array, incorporating a balun into your setup is a key step in achieving optimal signal clarity and strength.
Why Do I Need a Balun for My Innovantennas LFA Yagi in Ham Radio?
If you’re using an Innovantennas LFA Yagi antenna, incorporating a balun is essential for proper operation. The LFA Yagi is a balanced antenna, which means it requires a balanced feed line to function efficiently. A balun is necessary to convert the unbalanced signal from your coaxial cable into a balanced signal that the antenna can effectively use at the antenna feed point. Without a balun, you may encounter several issues, including reduced signal strength, increased noise levels, and even potential damage to your equipment. By ensuring a balanced feed, a balun helps maintain the integrity of your signal, providing you with the best possible performance from your Innovantennas LFA Yagi.
How to Choose the Right Balun for Your Antenna Feed Point
Selecting the appropriate balun for your antenna system involves considering several key factors. First, identify the frequency range of your antenna system and choose a balun designed to operate within that range. This ensures compatibility and optimal performance. For instance, using an air choke in constructing various types of baluns, such as the Ugly Balun, can be highly effective. Next, consider the power handling requirements of your system; the balun must be capable of handling the power levels you intend to use. It is also crucial to ensure a correctly balanced feed at the driven element to achieve optimal performance. Additionally, take into account the type of coaxial cable you are using, as the balun must be compatible with that specific type of cable. Finally, consider the physical constraints of your setup. Choose a balun that is compact and easy to install, fitting seamlessly into your existing antenna system. By carefully evaluating these factors, you can select a balun that will enhance the performance and reliability of your antenna system.
Hopefully this helps to clear things up for those that are unsure about baluns and where to use them. I was unsure what their real purpose was when I first started out and the 'what is a balun and do I need one?' is still one of the most commonly asked questions today.
