Active Projects & Case Studies

The Advanced Tuner App is a modular pitch detection platform built on the WebAudio API, designed to run natively in web browsers and on mobile devices without requiring a native install.

At its core, the system uses custom DSP algorithms to analyze incoming audio frequency data in real time and identify pitch with high accuracy across a broad range of instruments and tuning systems.

The modular architecture allows individual detection and analysis components to be developed, tested, and extended independently — making it adaptable for both general-purpose tuning and specialized musical research applications.

This is a client-backed web and mobile application centered on algorithmic melody generation.

The platform was developed in partnership with a private client and is built on proprietary compositional algorithms.

Further details cannot be released due to a non-disclosure agreement.

Many historical woodwind instruments exist only in museum collections or private hands — physically inaccessible for study, performance, or reproduction.

This project applies historical musicology and acoustic science to recreate the sonic profiles of these instruments using 3D design and additive manufacturing, without requiring access to the originals.

Each reproduction is subjected to rigorous acoustic verification and experimental testing to validate its fidelity to historical references.

The goal is to make the sound of the past accessible — to researchers, educators, and performers alike.

This project was initiated to address a specific accessibility need: a student requiring a wind instrument adapted to their physical capabilities.

In collaboration with the Music Education faculty at a Canadian university partner, IREM is designing and fabricating a 3D-printed soprano recorder tailored to that student's needs.

The project draws on additive manufacturing's ability to rapidly iterate custom geometries — adjusting key placement, instrument weight, and ergonomics in ways that traditional manufacturing cannot.

It sits at the intersection of inclusive design, music education, and applied fabrication research.

This study is being prepared to address a foundational question in acoustic fabrication: can additive manufacturing produce wind instruments with acoustic properties comparable to those made from traditional materials?

The research will systematically evaluate FDM and SLS-printed specimens against established acoustic benchmarks, examining factors such as wall resonance, internal surface finish, air-tightness, and tonal response.

The findings are intended to contribute baseline data to the broader field of acoustics and to inform IREM's own fabrication practices going forward.

Not every project is an instrument. This piece was an exercise in printing delicate, organic forms — thin petals, curved stems, and translucent surfaces that are difficult to reproduce cleanly with additive manufacturing.

Working in clear resin let us study how light passes through printed geometry and how fine features hold up at small scale — lessons that carry directly back into our precision instrument and component work.

Oboists shape their own reeds, and the shaper that defines a reed's profile is a precise — and often costly — piece of tooling.

IREM designed and 3D-printed a shaper that sets the reed blank's profile, making it possible to experiment with reed geometry and study how small changes affect response and tone.

It's a small tool with an outsized impact: faster iteration, lower cost, and a direct bridge between fabrication and playing.