Новини світу мікро- та наноелектроніки

 Keysight Technologies introduced its next-generation Infiniium XR8 Real-Time oscilloscopes, designed to accelerate high-speed digital and compliance testing while improving efficiency and insight for modern electronics development.

As interface standards such as USB, DisplayPort, and DDR rapidly evolve and scale in speed and complexity, engineers face tighter margins, higher data rates, and compressed development timelines. These pressures result in longer validation cycles, reduced noise tolerance, and growing lab constraints. The Infiniium XR8 addresses these challenges with a completely new hardware and software architecture optimised for today’s high-speed digital applications and emerging standards, helping engineering teams condense days of testing into hours.

The XR8 integrates newly designed front-end ASIC technology and an integrated ADC and DSP digital engine to preserve signal integrity, improve timing accuracy, and deliver consistent, repeatable measurements across high-speed serial, memory, and mixed-signal designs. These capabilities are essential for debugging and validating today’s high-speed interface, where small impairments in signal quality can directly impact system performance and compliance margins.

A redesigned mechanical architecture further enhances usability by reducing system power consumption, improving thermal efficiency, and minimising acoustic noise with a compact footprint. Engineers can deploy high-performance oscilloscopes in space-constrained labs and dense validation environments while maintaining a stable, low-noise operation.

Powered by Keysight’s new Infiniium 2026 software platform, the XR8 delivers faster response time, improved stability, and streamlined workflows for high-speed digital and compliance testing. The modern user experience features flexible waveform windows, enhanced visualisation, and productivity tools such as drag‑and‑drop functionality and an integrated SCPI recorder. Optimised multithread processing and memory management enable engineers to fully leverage Keysight’s measurement science, delivering enhanced jitter decomposition, PAM analysis, and advanced equalisation for deeper insight and faster validation.

Together, the new hardware and software architecture enable: 

Maximised test margin and signal integrity

Intrinsic jitter as low as 13 fs rms and noise performance below 130 µV at 8 GHz bandwidth provide exceptional fidelity and preserved compliance margin, enabling confident validation of high-speed interfaces including USB4v2, DisplayPort 2.1, and DDR5. 

Accelerated compliance testing efficiency

A new ADC and DSP digital engine combined with Infiniium 2026 software accelerates acquisition, analysis, and reporting by up to three times, dramatically reducing validation cycles and improving overall test throughput. 

Compact, quiet, and flexible lab deployment

Lower power consumption, enhanced thermal design, and reduced acoustic noise create a smaller, more flexible platform that can be positioned closer to the device under test while supporting comfortable, distraction-free daily engineering workflows.

Jun Chie, Vice President, Keysight Product Management, said: “Our customers are under intense pressure to validate increasingly complex, high-speed designs on compressed schedules. The Infiniium XR8 directly addresses that reality, preserving signal fidelity, accelerating compliance workflows, and reducing lab constraints in a single, streamlined platform. It’s about giving engineers back time, confidence, and productivity when they need it most.”

“As India strengthens its leadership in AI data centres, 5G-Advanced, next-generation computing, and aerospace and defence, signal integrity measurement challenges are becoming increasingly complex,” said Girish Baliga, General Manager, Industry Marketing, Keysight India. “The Infiniium XR8 oscilloscope delivers the precision and performance required to accelerate innovation while ensuring accurate, high-speed validation. As India advances its ‘Make in India’ vision and expands its global R&D footprint, demand for ultra-high-speed digital test solutions continues to grow. The XR8 empowers local engineering teams with the confidence and efficiency needed to bring world-class technologies to market faster.”

The post Keysight launches next-gen Infiniium XR8 Oscilloscopes for faster analysis, clearer insights, and a compact design appeared first on ELE Times.

Surface acoustic wave (SAW) filters may sound exotic, but they are everyday workhorses in wireless front-ends. Compact, cost-effective, and reliable, they shape signals with precision while keeping designs simple.

This quick primer walks through the basics—what they do, why they matter, and how they fit into modern communication systems.

SAW filter fundamentals

SAW filters exploit the piezoelectric effect to convert electrical signals into acoustic waves and back again. At their core, they consist of two interdigital transducers (IDTs) patterned on a piezoelectric substrate. The input IDT launches acoustic waves from the incoming electrical signal, while the output IDT reconverts those waves into an electrical signal.

Together, they form a bidirectional transversal filter. Absorbers are placed at the ends of the substrate to suppress unwanted reflections, ensuring clean signal transmission and stable filter response.

Figure 1 Drawing illustrates the basic architecture of a SAW filter, with input/output IDTs transducing signals across a piezoelectric substrate, while absorbers suppress reflections. Source: Author

Note that the wave produced by the output transducer represents only half of the full signal. Thus, if a 3-dB loss is observed at the output, the combined insertion loss of the input and output transducers amounts to 6 dB.

Each transducer consists of periodic interdigital electrodes connected to two busbars, which link to the electrical source or load. The electrode length governs amplitude, electrode position sets phase, and electrode wavelength defines the operating frequency of the SAW filter.

On a historic note, surface acoustic waves were first described by Lord Rayleigh in 1885 and are therefore often called Rayleigh waves. In his classic paper, Rayleigh predicted their propagation properties, noting that SAWs contain both longitudinal and vertical shear components that couple with the medium at the surface.

Their energy is confined to the substrate surface. Because SAWs are accompanied by electrostatic fields, electroacoustic conversion can be achieved through IDTs. Shaped like crossed fingers, these electrodes launch and receive the waves, forming the basis of modern SAW devices.

At its core, a SAW filter operates by converting electrical energy into acoustic energy on a piezoelectric substrate. This process is driven by two interdigital transducers: the input transducer generates acoustic waves from the incident electrical signal, and the output transducer reconverts them into electrical energy.

Because each transducer launches waves equally in the +X and –X directions, the device functions as a bidirectional transversal filter. Since only half of the launched wave (+X direction) is useful, a 3-dB loss is observed. Taken together, the input and output transducers yield a total insertion loss of 6 dB.

SAW filter applications

Due to their excellent selectivity, low insertion loss, and compact size, SAW filters have become indispensable across modern RF systems. In mobile communication devices such as smartphones, base stations, and repeaters, they suppress interference and maintain clean signal channels.

Wireless LAN and Bluetooth modules rely on them to preserve frequency integrity and reduce crosstalk, while GPS receivers use SAW filters for precise frequency selection that enhances location accuracy. In broadcasting and television tuners, they improve signal quality and selectivity.

Beyond consumer electronics, SAW filters are widely adopted in IoT devices, automotive electronics, and satellite communication systems, where their reliability and small footprint make them a cornerstone of high-performance RF design.

As a familiar practical example, I remember 38.9 MHz SAW filters were a staple in television receivers, serving as intermediate‑frequency (IF) filters in tuner modules. They provided sharp selectivity for separating video and audio signals, ensuring clear picture and sound quality. In fact, paired designs often used a 38.9 MHz SAW filter for the video IF and a companion filter around 33.4 MHz for the audio IF, enabling precise audio separation in PAL/SECAM systems.

Beyond TVs, the same frequency was also used in audio IF stages of broadcast receivers and set‑top boxes, where the compact size and stable response of SAW filters made them a reliable choice for consumer electronics.

Below figure shows a niche and potentially legacy 38.9 MHz SAW filter used in PAL/SECAM television receivers as the video IF filter. In these systems, the filter provides sharp selectivity to isolate the video carrier, while a companion SAW filter at 33.4 MHz is employed for the audio channel.

Figure 2 A 38.9-MHz SAW filter shows its pinout and package design for television receiver applications. Source: Author

Together, this pair enabled precise separation of picture and sound in analog TV tuners, with the compact package and stable frequency response making SAW filters the standard choice in consumer television receivers.

As a quick aside, dual-output SAW filters were also in use at that time, designed to handle both picture and sound carriers simultaneously. The picture IF carrier was set at 38.90 MHz, while the sound IF carrier was offset at 33.4 MHz, reflecting the 5.5 MHz spacing defined in PAL/SECAM systems.

SAW filter practice pointers

This session offers some practical pointers on working with SAW filters, based on their established role in communication and signal-processing systems.

Recall that SAW filters operate on the principle of the piezoelectric effect: an applied voltage induces a mechanical wave on a crystal, while mechanical pressure conversely produces a change in potential difference. When an RF voltage is applied to the input transducers, it generates an acoustic surface wave that travels across the crystal to the output transducer, where it’s reconverted into an electrical signal.

By carefully designing the electrodes—typically comb-shaped with interlocking fingers—engineers can tailor frequency transmission characteristics through precise control of finger size, number, and spacing.

Compared with conventional filters that rely on coils and capacitors, SAW filters are smaller, more affordable, and offer superior long-term stability. They require no tuning and deliver significantly better performance, which explains their widespread adoption in color television sets and video recorders worldwide.

Beyond these, SAW components are also integral to satellite receivers, cordless phones, mobile devices, automotive keyless entry systems, garage door openers, and numerous other applications.

Next, a SAW resonator is a key component in low-cost 433 MHz RF modules. It’s used in the transmitter module as a precise, fixed-frequency oscillator to ensure stable operation at 433.92 MHz within the unlicensed ISM band.

Figure 3 SAW resonator enables a compact, low-cost architecture for 433-MHz RF transmission. Source: Author

Getting into the criteria for choosing a SAW filter, many specifications must be carefully evaluated. Key parameters include the center frequency, bandwidth, insertion loss, and out-of-band rejection, since these directly determine how well the filter isolates the desired signal from interference. Group delay and passband flatness are also critical for maintaining signal integrity, especially in communication systems where timing accuracy affects bit error rates.

Designers must further consider package size, environmental stability, and repeatability, ensuring the filter performs reliably under temperature variations and mechanical stress. Finally, cost, availability, and compliance with regulatory standards often guide the final choice, balancing performance with practical constraints.

Figure 4 A sample datasheet snip highlights the operating conditions and electrical characteristics of a randomly picked 480-MHz SAW filter. Source: ESC Inc.

Side note: The ECS-D480A 480 MHz SAW filter is now obsolete, yet it remains a useful reference for understanding how compact SAW devices were once applied in RF systems. At this frequency, such filters were typically deployed in satellite receiver intermediate-frequency stages, where sharp band-pass selectivity was critical after down-conversion.

They also found roles in wireless communication front-ends and certain measurement instruments, valued for their ability to provide narrowband filtering and suppress adjacent channel interference. Do not panic about this obsolescence—SAW filters are still widely available today from multiple vendors, offered in both thru-hole and, more commonly, SMD form for modern RF and wireless applications.

And, integrated SAW filters enable multi-channel usage within a single radio front-end, allowing several selective paths to be consolidated into one compact device. This integration reduces board space, simplifies design, and supports efficient handling of multiple frequency bands in modern receivers.

There are voltage-controlled SAW oscillators (VCSOs) as well, which add electrical tunability to the otherwise fixed-frequency concept. By applying a control voltage, their oscillation frequency can be shifted, making them valuable in agile radios, test instruments, and wireless platforms that demand dynamic channel agility and adaptive interference suppression.

Moreover, SAW filters operate along the surface of the substrate, making them well-suited for mid-band frequencies and compact designs. Around the early 2000s, bulk acoustic wave (BAW) filters were introduced, driving acoustic waves through the bulk of the material to reach higher operating frequencies and stronger power handling.

In practice, SAW devices remained the mainstay for intermediate-frequency stages and mid-band wireless, while BAW devices gradually took hold in high-frequency front-ends such as LTE, 5G, and Wi-Fi.

Next steps

As it seems, SAW filters carry a distinctive experimental appeal in ham radio, where their sharp selectivity and compact footprint make them ideal for signal-chain exploration—even though their primary role has long been in commercial systems.

Anyway, they are not a casual undertaking for hobbyists: working at these frequencies demands care, proper instrumentation, and patience. Still, salvaged parts from old TV boards and consumer gear can provide a practical gateway into serious tinkering.

While this serves as a quick wrap-up—with more to explore another time—it’s clear that engineers are naturally drawn to SAW filters for their importance in frequency-domain design and their resonance with ham radio practice. Yet curious builders should not hesitate—experiment, learn, and share. The community thrives on grassroots exploration, and your work could well spark the next wave of practical insights.

T. K. Hareendran is a self-taught electronics enthusiast with a strong passion for innovative circuit design and hands-on technology. He develops both experimental and practical electronic projects, documenting and sharing his work to support fellow tinkerers and learners. Beyond the workbench, he dedicates time to technical writing and hardware evaluations to contribute meaningfully to the maker community.

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