It doesn’t take a crystal ball to know where the future of wireless is heading. With inexhaustible demand driven by 5G, 6G, and beyond — as well as ultra-high-definition video, autonomous driving cars, security applications, and IoT — the sky’s the limit for utilizing the higher ends of the electromagnetic (EM) spectrum.

Meeting this demand requires products capable of capitalizing on the millimeter-wave (MMW) bands that presently cover the frequencies between 30 GHz and 500 GHz; however, these higher frequencies present a significant problem that design engineers must address: that of standing waves. Without control, these unwanted waves can attenuate power output, distort the digital information on the carrier, and in extreme cases, damage internal components.

To counteract the problem of standing waves at lower microwave frequencies, engineers rely on Faraday rotation isolators — more commonly referred to simply as isolators. At their very basic level, isolators are two-port, input and output components that allow EM signals to pass in one direction but absorb them in the opposite direction. Traditional isolators fall short at the higher frequencies required for next-gen wireless applications.

Virginia Diodes, Inc. manufactures test and measurement equipment — such as vector network analyzers, spectrum analyzers, and signal generator extension modules — for MMW and THz applications.

A big part of the problem is that the first isolators were designed more than a half-century ago, with very few modifications since the original concept. With recent advancements, however, companies at the cutting edge of MMW technologies are gaining the ability to launch products that operate optimally at stratospheric frequencies.

“The new series of waveguide isolators has been a key enabling technology for VDI, and a large advance from what was previously available,” said Jeffrey Hesler Ph.D., CTO of Virginia Diodes, Inc., a Virginia-based manufacturer of test and measurement equipment — such as vector network analyzers, spectrum analyzers, and signal generator extension modules — for MMW and THz applications.

“The compact size, extremely low insertion loss, and the wide bandwidth have allowed us to use isolators in a wider variety of our systems than was previously possible and have led to significant improvements in key system performance metrics such as source power and sensitivity,” said Hesler.

Properties of Isolator Functionality

By understanding these advancements in each of the five properties of isolator functionality, designers can better harness isolators to improve their MMW products.

For traditional isolators, insertion loss is low in the microwave bands but at MMW frequencies, the loss becomes increasingly problematic; for instance, in the WR-10 band, the insertion loss can exceed 3 dB, meaning half of the signal power is lost. In the WR-5.1 band, the loss climbs to more than 5 dB. Because of high losses, traditional isolators are often precluded for use in MMW systems.

1. High isolation. Isolation is a measure of how much of the signal traveling in the reverse direction passes back through the isolator. Because isolators are intended to prevent or minimize this from happening, the higher the isolation, the better.

The issue that MMW system designers face is impedance mismatches and the resulting reflections between components. In MMW systems, the distance between components is often more than a wavelength, putting reflected signals out of phase. The out-of-phase reflected signal can perturb the operating point of the upstream component. As you sweep frequencies, the phase changes and you get nulls, dips, and degraded performance; however, when you insert an isolator between components, the reflected signal gets absorbed and the problem goes away.

The highest possible isolation occurs when the reverse wave is rotated exactly 45° into the plane of the isolator’s resistive layer. Isolation can degrade by as much as 10 dB when the signal rotation is off by just 1°. The only way to confirm such precision is to fully characterize each isolator on a vector network analyzer. This validates total compliance, as opposed to just spot-checking at a couple of frequencies in the band.

2. Low insertion loss. While isolation is the namesake of these components, the suppression of the reverse wave can’t come at the expense of attenuating the forward input signal. Insertion loss is a measure of how much loss a signal incurs as it passes through the isolator in the forward direction.

For traditional style isolators, insertion loss is low in the microwave bands but at MMW frequencies, the loss becomes increasingly problematic; for instance, in the WR-10 band (75-110 GHz), the insertion loss can exceed 3 dB, meaning half of the signal power is lost. In the WR-5.1 band (140-220 GHz), the loss climbs to more than 5 dB. Because of high losses, traditional isolators are often precluded for use in MMW systems.

A designer’s main fear is that the isolator will significantly degrade the strength of the final output. It can be frustrating for engineers to try and tune the standing waves out of each system, usually with limited success. Many of the alternate methods used are narrowband in nature, so that the solution may work well only over an insufficiently narrow band of frequencies.

Faraday rotation isolators operate by using ferrite discs to rotate the signal; however, the traditional method to manufacture them has been to use ferrites that are substantially longer than the minimum required length and then tune the magnetic bias field to achieve optimal performance. This delivers good isolation but at a much higher insertion loss. There is a twofold problem with this workaround. First, there is more of the lossy ferrite in the signal path and second, the ferrite loss parameter increases at lower magnetization levels.

To minimize loss, it is essential that the ferrite length be reduced as much as possible. An isolator design developed for NASA for WR-15 through WR-3.4 (50 GHz to 330 GHz) applications saturates the ferrite with a strong magnetic bias field, which allows for the shortest possible length of ferrite to achieve the ideal 45° of rotation. This lowers the insertion loss to less than 1 dB at 75-110 GHz and only 2 dB at 220-330 GHz.

“The extension of isolator technology above 220 GHz is an impressive technical feat and a key technology that enables us to deliver accurate measurements with higher sensitivity than we were previously able to achieve,” noted Hesler.

3. Low port reflection. A good isolator must also have low port reflections. Voltage Standing Wave Ratio (VSWR) is a measure of the reflections at the input and output ports. A good range at MMW frequencies is 1.5:1 or less; 1:1 equals no reflection.

The importance of low port reflections is often overlooked. An isolator with high port reflections creates an alternate set of standing waves. The adjacent components are still adversely impacted by out-of-phase signals reflected back into their ports. High isolation and low insertion loss are of little value if the port reflections are large.

4. High power rating. Power in the reverse traveling signal is absorbed in the isolator, resulting in heat. The more heat it can handle, the higher the power rating. Historically, high heat was not an issue as there was very little power available at MMW frequencies; however, as higher power sources become available, the importance of power ratings increases.

To handle the problem of high heat loads, some newer isolators are already incorporating diamond heat sinks into their design. Diamond effectively channels heat from the resistive layer in the isolator to the metal waveguide block and thus lowers operating temperatures for improved reliability.

To handle the problem of high heat loads, some newer isolators are already incorporating diamond heat sinks into their design. Diamond is the ultimate thermal conductor, approaching 2200 W/m•K (watts per meter Kelvin) — more than five times higher than copper. Diamond effectively channels heat from the resistive layer in the isolator to the metal waveguide block and thus lowers operating temperatures for improved reliability.

5. Small footprint. Minimizing the size and weight of MMW components is especially important in today’s wireless applications. A standard traditional-style isolator in the WR10 band is about 3'' long, with a cylindrical section in the center that’s about 1.3'' in diameter. But the newest design shapes are rectangular and can be as small as 0.75'' per side and 0.45'' thick.

The same technology used to reduce insertion loss — utilizing the shortest possible length of ferrite — also partially accounts for the reduction in footprint.

Conclusion

In addition to the five critical characteristics, other properties of modern isolators improve their utility at MMW frequencies; for instance, wide bandwidth. Standard waveguide bands typically extend to 40% on either side of the center frequency. Newer, high-performing isolators operate over extended bandwidths exceeding 50% from center frequency, giving designers greater freedom to build more bandwidth into their systems.

Additional advances include isolators that operate in cryogenic conditions, which is critical because a traditional isolator designed for room-temperature operation will perform poorly when cooled.

This article was written by Diane Kees, COO of Micro Harmonics Corporation, Fincastle, VA. For more information, visit here .

Aerospace & Defense Technology Magazine

This article first appeared in the April, 2020 issue of Aerospace & Defense Technology Magazine.

Read more articles from this issue here.

Read more articles from the archives here.