Tag: acoustic

Breggz Introduces the First Wireless In-Ear Headphones Certified for IMAX Enhanced – CES 2026

At CES 2026, Amsterdam-based consumer audio specialist Breggz announces that the Zohn-1, a true high-end wireless in-ear hearable offering pristine sound, has partnered with IMAX® and DTS® to introduce the first wireless in-ear earphones with IMAX® Enhanced certification.

IMAX Enhanced device certification ensures consumer electronics devices meet the highest standards, delivering the renowned IMAX immersive experience on personal devices for the highest-quality entertainment experiences wherever fans are watching. The IMAX Enhanced certification of the Breggz Zohn-1 introduces a new device category to the program, enabling consumers to experience the highest fidelity sound on qualifying in-ear hearables, complementing the IMAX Enhanced-certified suite of TVs, PC laptops, tablets, mobile phones, AVRs, loudspeakers and soundbars.

“Breggz is proud to be the first wireless in-ear hearable certified for IMAX Enhanced, introducing a new device category to unlock more premium experiences on personal devices,” says singer/artist and Breggz founder Xander de Buisonjé. “IMAX embodies what I intended when founding Breggz; I just want the world to hear what I hear.” Continuing, “Artists and filmmakers spend significant time and effort to deliver the best possible audio quality, but hearing the poor sound quality of in-ear hearables puts all that hard work and creative intent to waste—this is why I had to introduce the Zohn-1.”

“IMAX Enhanced is about delivering best-in-class, premium experiences that honor creative intent, making our partnership with Breggz a natural fit,” said Giovanni Dolci, Chief Commercial Officer at IMAX. “By expanding IMAX Enhanced into a premium in-ear device, we’re growing the IMAX Experience and giving fans a way to enjoy content with the same clarity, power, and intent that artists and filmmakers hear.”

The Zohn-1 is recognised for introducing four groundbreaking audio principles into the wireless in-ear headphone—perfect anatomical fit, advanced balanced acoustic drivers, sophisticated microprocessing and greater personalization. Through these principles, Breggz introduces a new kind of listening experience, one that adapts to you. Designed for how people watch and listen today, the Breggz and IMAX partnership creates a more personal and immersive connection to content, deepening fandom and making every moment feel closer, richer, and more intentional.

To learn more about the Breggz Zohn-1: www.breggz.com

To learn more about the IMAX Enhanced programme, visit IMAX and DTS at the Aria Resort & Casino Penthouse Sky Suites at CES – Consumer Electronics Show in Las Vegas from January 6-9. www.imax.com

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QCY MeloBuds N70 Review

QCY, a global leader in the wireless audio industry has unveiled the QCY MeloBuds N70—its latest flagship true wireless Active Noise Cancellation (ANC) earbuds designed to bring more clarity, control, and comfort to everyday listening. With a powerful dual-driver system including a high-sensitivity MEMS tweeter, refined acoustic structure, and adaptive noise cancellation that adjusts in real time, the innovation is built to sound better in every moment and we have been testing these out the last few weeks and they are impressive for the price and stick it up to others in the market that cost much more, check out the full hands-on review below.

Dual-driver synergy for deeper, clearer sound

The MeloBuds N70 pairs a 10mm ring-shaped liquid silicone dynamic driver with a high-sensitivity MEMS tweeter, blending deep, rich full-bodied bass with crisp, articulate highs. Working in tandem, the two powerful drivers form a spacious, well-layered soundstage that highlights texture, separation, and tonal nuance with impressive precision, to deliver audio quality that approaches HiFi-level performance. Whether you’re listening to richly produced playlists, dialogue-driven podcasts, or immersive gaming soundtracks, the N70 brings out the subtle textures that keep every session engaging. 

Refined design that sharpens treble and refines space

To bring treble forward with greater clarity and precision, the MeloBuds N70 features a custom tweeter sound guide that extends high-frequency response across a wide 20Hz–40kHz range. This is complemented by QCY’s dual acoustic guide tube, which regulates airflow between the drivers to reduce resonance and phase shift. A balanced driver layout helps maintain stereo integrity by minimizing phase distortion and keeping left–right channel alignment consistent, to ensure that spatial cues stay sharp, vocals remain defined, and directional details hit with striking clarity.

 

Smarter Noise Control that tuned to your surroundings
The MeloBuds N70 features adaptive Active Noise Cancellation (ANC), a technology that reduces unwanted ambient sound for clearer, more focused listening. With up to -56dB of suppression across an ultra-wide 5.5kHz bandwidth, the system intelligently adjusts in real time by analyzing both surrounding noise and in-ear fit to automatically optimize cancellation strength. Whether easing off in a quiet café or ramping up on a busy train, it keeps ear pressure low and clarity high without the need for manual toggling. For added flexibility, users can also fine-tune ANC levels via the QCY app.

For calls, a three-microphone array per earbud helps isolate your voice with beamforming tech and an inward-facing mic that captures speech directly from within the ear canal. A wind-resistant mesh, acoustic chamber, and anti-wind DSP algorithm further reduce wind noise, supporting clearer conversations even in breezy environments.

Fast Charging and Wireless Power for Week-Long Use

QCY MeloBuds N70 delivers enduring battery performance built for extended daily use. On a single charge, the earbuds provide up to 10 hours of continuous playback, with the charging case extending total battery life to as much as 50 hours, which helps minimize the need for frequent power top-ups throughout the week. When time is limited, a 10-minute quick charge gives up to 2 hours of use, keeping users powered through last-minute plans.

The case also supports both wired and wireless charging, offering flexible and convenient ways to stay charged on the go. Designed for real-world use, it features soft dual-layer silicone tips in five sizes for a secure, fatigue-free fit, and carries an IPX5 water resistance rating to handle sweat and light weather with ease.

Control and connect, your way

The MeloBuds N70 supports dual-device connection via the QCY app, letting you stay linked to two sources at once—like your phone and laptop—for seamless switching between calls, music, and meetings. Audio automatically prioritizes the active device for smooth multitasking. 

The QCY App

 

Availability & Price

Available in Midnight Black, Starlight Purple, Titanium Gold, the MeloBuds N70 combines acoustic depth with everyday usability in a clean, comfort-focused design. It is now available on QCY’s official store and through authorized retailers, with pricing starting at USD $59.99 (pricing may vary by market).

 

Product Link (US Amazon): https://www.amazon.com/dp/B0FHD4L86L

Official Website: https://www.qcy.com/products/qcy-melobuds-n70

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Video Review

Musical Instrument Design: The Art and Science of Crafting Sound

Musical instruments have been an integral part of human culture for millennia, serving as tools for expression, communication, and creativity. The design of these instruments is both an art and a science, blending craftsmanship, physics, and aesthetics to create devices capable of producing rich, expressive sounds. Whether ancient or modern, acoustic or electronic, the process of musical instrument design reflects a deep understanding of how materials, shape, and technique come together to influence sound quality and playability.

Foundations of Instrument Design

At its core, musical instrument design revolves around the production and manipulation of sound waves. Sound is created when an object vibrates, causing air molecules to oscillate and propagate waves that our ears perceive. Different instruments use varying mechanisms to generate these vibrations—strings vibrate, air columns resonate, membranes oscillate, or electronic circuits produce signals.

Understanding these physical principles is essential for designing an instrument that not only produces pleasing tones but also responds dynamically to the musician’s touch. For instance, the tension and length of a string affect its pitch, the shape and size of a drum’s head influence its resonance, and the bore of a wind instrument determines its harmonic series.

Materials Matter

Material selection is a fundamental aspect of instrument design. Wood, metal, plastic, and synthetic composites each impart unique tonal characteristics. For centuries, luthiers carefully chose woods like spruce or maple for their resonance and strength when crafting violins or guitars. Brass and bronze alloys have long been favored for horns and bells due to their durability and bright tonal qualities.

Interestingly, the design of an instrument can even aim to mimic natural sounds. Wind chimes, for example, are designed to evoke the sound of the wind, blending random patterns of resonance with gentle, airy tones that remind listeners of breezes rustling through leaves. Such inspirations highlight how instrument makers connect the physics of sound with human perception and emotion.

Shape and Structure

The shape and structure of an instrument are equally crucial. The geometry of a guitar’s body, for example, affects how sound waves reflect and amplify inside, directly impacting tone and volume. Wind instruments rely heavily on the shape and length of their tubing; a flute’s slender, straight design produces a pure, bright tone, while a curved saxophone generates a warmer, richer timbre due to its conical bore.

In percussion, the size and tension of drumheads influence pitch and sustain. Designers often experiment with dimensions, materials, and bracing patterns to create instruments that balance durability with the desired acoustic properties.

Moreover, the ergonomics of the instrument—how it feels to hold, play, and manipulate—are carefully considered. A well-designed instrument accommodates the physical demands of musicians, enabling comfortable, expressive performance. This human-centered design often evolves through feedback from players and iterative prototyping.

Innovation and Technology

While traditional craftsmanship remains foundational, technology has significantly expanded the horizons of musical instrument design. Computer-aided design (CAD) tools allow makers to model acoustics and ergonomics with unprecedented precision. Digital fabrication methods like 3D printing enable the creation of complex shapes and customized components previously impossible by hand.

Electronic instruments have revolutionized sound possibilities. Synthesizers, for instance, use electronic circuits to generate and manipulate audio signals, offering virtually infinite timbral variety. Even traditional instruments now often incorporate pickups and sensors, blending acoustic warmth with digital versatility.

These innovations challenge designers to blend the tactile qualities of traditional instruments with modern functionality, creating hybrid instruments that appeal to contemporary musicians.

The Role of Cultural and Historical Context

Musical instrument design cannot be separated from cultural and historical contexts. Instruments often carry symbolic meaning and reflect the musical styles of their time and place. The sitar’s resonant strings and sympathetic tones are intimately linked to Indian classical music, while the electric guitar’s design echoes the energy and rebellion of rock music.

Designers draw inspiration from these traditions while also pushing boundaries. Revivals of ancient instruments coexist with futuristic designs, reflecting ongoing dialogues between heritage and innovation.

Acoustic Challenges and Solutions

One of the persistent challenges in instrument design is managing acoustic feedback and unwanted noise. For example, string instruments can produce “wolf tones,” dissonant resonances that interfere with sound quality. Designers employ damping techniques, structural reinforcements, and selective material use to mitigate these effects.

In wind instruments, controlling airflow and preventing leaks is vital. Precision in key mechanisms and seals ensures accurate intonation and responsiveness. The engineering of valves, keys, and pads is often as important as the acoustic design itself.

Craftsmanship and Artistic Expression

Despite advances in technology, musical instrument design remains a deeply artisanal practice. The skill of the maker is visible in the fine details—the curvature of a violin’s scroll, the finish of a drum shell, or the hand-wound coils of a pickup.

These artistic touches not only influence aesthetics but also contribute subtly to sound quality. The balance between uniformity and individuality in handcrafted instruments creates a personal connection between maker, musician, and listener.

The Future of Instrument Design

Looking ahead, musical instrument design is poised for exciting developments. Advances in materials science may yield lighter, more durable instruments with enhanced acoustic properties. Artificial intelligence could assist in crafting instruments tuned to specific player styles or optimizing design parameters for new tonal possibilities.

Virtual and augmented reality technologies might transform how instruments are played and taught, integrating haptic feedback and immersive environments. Designers will continue exploring the boundaries of what an instrument can be, maintaining the essential link between sound, expression, and human creativity.

Conclusion

Musical instrument design is a rich and evolving field where science, craftsmanship, and art converge. By understanding the principles of acoustics, carefully selecting materials, and innovating with form and technology, designers create instruments that not only produce beautiful sounds but also inspire and empower musicians.

Whether evoking the gentle rustling reminiscent of the sound of the wind or delivering powerful, electrifying tones, musical instruments remain vital expressions of human culture and imagination. The ongoing dialogue between tradition and innovation ensures that the craft of instrument design will continue to flourish, producing new voices and enriching the world’s musical landscapes for generations to come.

 

Using sound waves to create a smart T-shirt

Imagine wearing a T-shirt that measures your breathing or gloves that translate your hand movements into commands for your computer. Researchers at ETH Zurich, led by Daniel Ahmed, Professor of Acoustic Robotics for Life Sciences and Healthcare, have laid the foundations for just such smart textiles. Unlike many previous developments in this area, which usually use electronics, the ETH researchers rely on acoustic waves passed through glass fibres. This makes the measurements more precise and the textiles lighter, more breathable and easier to wash. “They are also inexpensive because we use readily available materials, and the power consumption is very low,” says Ahmed.

Acoustic sensors embedded in fabric

The researchers call their development SonoTextiles. They have transformed normal fabrics into smart sensors that react to touch, pressure and movement. “While research has already been conducted into smart textiles based on acoustics, we are the first to explore the use of glass fibre in combination with signals that use different frequencies,” explains Yingqiang Wang, the first author of the study that has been published in the journal external pageNature Electronics.

The researchers have woven glass fibres into the fabric at regular intervals. At one end of each glass fibre is a small transmitter that emits sound waves. The other end of each of the glass fibres is connected to a receiver that measures whether the waves have changed.

Each transmitter works at a different frequency. This means it requires little computing power to determine which fibre the sound waves have changed on. Previous smart textiles often struggled with data overload and signal processing issues, since each sensor location had to be evaluated individually. “In the future, the data could be sent directly to a computer or smartphone in real time,” says Ahmed.

When a glass fibre moves, the length of the acoustic waves passing through it changes, as they lose energy. In the case of a T-shirt, this can be caused by body movement or even breathing. “We used frequencies in the ultrasonic range, around 100 kilohertz – well beyond the range of human hearing, which is between 20 hertz and 20 kilohertz,” Wang emphasises.

Highly versatile

The researchers have shown that their concept works in the lab. In the future, SonoTextiles could be used in a variety of ways: as a shirt or T-shirt, they could monitor the breathing of asthma patients and trigger an alarm in an emergency.

The material remains elastic despite the interwoven glass fibres. The sound waves measure when someone breathes in and out. (Video: Daniel Ahmed / ETH Zurich)

In sports training and performance monitoring, athletes could receive real-time analysis of their movements, to optimise their performance and prevent injuries. The textiles also have potential for sign language: gloves with this technology could simultaneously translate hand movements into text or speech. They could also be used in virtual or augmented reality environments.

“SonoTextiles could even measure a person’s posture and improve their quality of life as an assistive technology,” adds Chaochao Sun, who shares first authorship of the study. People who want to improve their posture could receive targeted feedback to correct poor posture. The textiles could also indicate when a wheelchair user needs to change position to prevent pressure ulcers.

Although the everyday usability of SonoTextiles is potentially very high, Ahmed adds that there is still room for improvement in terms of practical application. Glass microfibres worked well as sound conductors in the lab, but they could potentially break in everyday use. “The beauty is that we can easily replace the glass fibres with metal. Sound also propagates effectively through metal,” explains Ahmed, adding “We would like to expand our research in this direction and also into other applications.” The researchers now want to make the system more robust and examine how the electronics can be better integrated into the textiles.