In a remarkable leap forward for display and audio technology, researchers at Pohang University of Science and Technology (POSTECH) have unveiled a groundbreaking innovation that blurs the boundaries between sight and sound. Led by Professor Su Seok Choi from the Department of Electrical Engineering and PhD candidate Inpyo Hong from the Graduate Program in Semiconductor Materials and Devices, the team has pioneered the world’s first Pixel-Based Local Sound OLED technology. This revolutionary development fundamentally transforms each pixel of an OLED panel into a distinct sound emitter, effectively turning the entire display into a multichannel speaker array. Such a display no longer merely presents images but simultaneously orchestrates precise, localized audio outputs, heralding a new era in immersive visual and auditory experiences.
The significance of this breakthrough lies in its ability to infuse sound directly into the display without requiring external speakers. Traditionally, delivering high-fidelity, multichannel audio in compact devices has demanded the use of bulky soundbars or multiple speaker units, often compromising design aesthetics and spatial constraints. In particular, environments such as vehicle interiors, where space is limited and design integration is critical, pose substantial challenges to embedding multiple conventional speakers. POSTECH’s innovation circumvents these issues by embedding ultra-thin piezoelectric exciters within the OLED panel, enabling sound emission from each pixel itself. This integration preserves the slim, flexible form factors that have made OLED displays highly sought after, while delivering rich, localized audio.
OLED displays have been at the forefront of the display technology landscape due to their vibrant color reproduction, deep blacks, and flexible substrates. Despite these advances, the auditory experience has remained a secondary concern, reliant on peripherals. The POSTECH team’s approach reimagines the OLED display as a multisensory interface. By embedding piezoelectric vibration arrays beneath the OLED pixels, the technology converts electrical driving signals into mechanical vibrations, which generate sound waves directly from the screen. Such a configuration ensures tight synchronization between visual content and its corresponding sound, elevating user immersion to unprecedented heights.
A key technical challenge historically limiting integrated sound displays has been sound crosstalk, where audio signals from neighboring speakers interfere with each other, blurring spatial sound cues. POSTECH has addressed this by developing a crosstalk-free method that guarantees sound from each pixel maintains clear spatial isolation. The team’s design dramatically improves sound localization accuracy, which traditional multichannel speaker arrays often fail to deliver, especially in thin, flexible panels. Achieving this required a sophisticated arrangement of piezoelectric exciters synchronized with the OLED pixel grid and advanced control algorithms for sound wave emission, ensuring crisp, multi-directional soundscapes from a single display unit.
The prototype, successfully demonstrated on a 13-inch OLED panel commonly found in laptops and tablets, validates the practical feasibility and scalability of this technology. This panel’s size and resolution affirm that such pixel-level sound control can be realized on commercially relevant devices, opening doors for integration into a variety of form factors, from mobile phones to automotive dashboards. The acoustic performance rivals, and in some respects surpasses, that of conventional speaker systems, without sacrificing the display’s sleekness. This flattening of the audio-visual hardware hierarchy promises radical redesign opportunities in consumer electronics, where display real estate and auditory clarity converge seamlessly.
Integrating Pixel-Based Local Sound in devices extends sensory interaction beyond mere visual presentation, enabling new paradigms in information delivery and entertainment. For example, in an automotive setting, this technology permits distinct audio streams to emanate from specific regions on the screen, allowing simultaneous yet isolated auditory experiences. A driver can hear navigation prompts localized to one part of the display, while passengers enjoy different content elsewhere, all without external speaker arrays cluttering the cabin. Such precise spatial audio control enhances driver focus and passenger enjoyment, fundamentally altering in-car multimedia experiences.
Beyond automotive applications, the implications for virtual reality (VR), augmented reality (AR), and mobile devices are profound. The seamless integration of dynamic, spatially localized sound tied directly to visual pixels can greatly enhance perception within immersive environments, enabling audible cues that correspond exactly with on-screen elements in three-dimensional space. This synchronization breaks down barriers between digital content and human sensory perception, fostering heightened realism and interactivity. Moreover, devices can become lighter and thinner by eliminating the need for conventional speaker hardware, while maintaining or improving sound quality and immersion.
The technical innovation centers on embedding ultra-thin piezoelectric exciters delicately articulated within the OLED frame. Piezoelectric materials deform mechanically when an electrical voltage is applied, producing vibrations. These minute vibrations propagate through the display substrate, emitting sound waves. Positioning these exciters in pixel-aligned arrays ensures that every pixel can be controlled to emit specific audio frequencies and amplitudes. Crucially, the exciters’ design accommodates the OLED’s delicate electronic layers and thin form factor, avoiding damage and preserving display performance—a feat requiring precision engineering at the micro and nanoscale.
POSTECH’s research further includes a novel method to suppress acoustic crosstalk, a common issue in multi-emitter sound systems. Through intricate signal processing and hardware design, the team engineered a vibration pattern that cancels interfering waves between adjacent pixels. This innovation preserves the integrity of independent audio channels, a necessity for complex soundscapes with multiple simultaneous audio sources. This kind of isolation could not be realized previously in integrated speaker arrays due to physical constraints, marking a pivotal advance in sound engineering for display technologies.
Professor Su Seok Choi emphasized the transformative potential of this integrated sound display technology, stating, “Displays are evolving beyond visual output devices into comprehensive interfaces that engage both sight and sound. This technology can become a core feature in next-generation electronics, facilitating sleek, lightweight designs in smartphones, laptops, and automotive displays while delivering immersive, high-fidelity audio.” Such convergence embodies the future of multimedia devices, where sensory engagement is holistic and seamless, bridging auditory and visual channels with unprecedented fidelity.
Funding support from the Ministry of Trade, Industry and Energy under the Electronic Components Technology Innovation Program, combined with academic backing from POSTECH’s Graduate Program in Semiconductor Materials and Devices, has been crucial in propelling this innovation from theoretical concept to functional prototype. The published results in the esteemed journal Advanced Science underscore the scientific rigor and breakthrough quality of the work. This research sets a benchmark for future endeavors seeking to merge complex sensory outputs within compact, multifunctional devices.
Looking forward, the prospects for Pixel-Based Local Sound OLED technology extend well beyond consumer electronics. Industries such as healthcare, aviation, and smart environments could harness these displays to deliver context-aware, immersive audio-visual content tailored to specific users or situations. Imagine medical monitors projecting alerts with direct localized audio cues, or smart home interfaces conveying notifications through discrete sound zones. By embedding rich, spatially distinct sound within high-definition displays, POSTECH’s innovation redefines how humans may interact with technology in the near future.
In summary, POSTECH’s development of the world’s first Pixel-Based Local Sound OLED heralds a paradigm shift in display technology, merging ultra-thin piezoelectric acoustic emitters with OLED panels. This allows each pixel to function as a precise, independent sound source free from crosstalk, demonstrated on a real 13-inch panel suitable for laptops and tablets. This unique confluence of slim design, high-definition visuals, and immersive audio paves the way for sleeker, smarter multimedia devices across sectors including automotive, VR, and mobile technologies. Beyond aesthetics or convenience, it fundamentally reshapes sensory engagement, bringing sight and sound together in perfectly synchronized harmony.
Subject of Research: Pixel-Based Local Sound OLED Technology Integrating Piezoelectric Vibration Arrays for Crosstalk-Free Multichannel Audio in Displays
Article Title: Localized Sound-Integrated Display Speaker Using Crosstalk-Free Piezoelectric Vibration Array
News Publication Date: 25-Apr-2025
Web References: 10.1002/advs.202414691
Image Credits: POSTECH
Keywords
Applied sciences and engineering; Physics; Sound; Applied optics; Optical devices; Display technology; Vibration; Oscillations; Computer science; Computer processing; Image processing; Pixel counting; Machine vision; Engineering; Automotive engineering
Tags: advanced display technologycompact sound solutionshigh-fidelity audio in devicesimmersive audio-visual experienceintegrated audio systemsmultichannel audio innovationOLED display technologypiezoelectric exciter technologyPixel-Based Local SoundPOSTECH research breakthroughsProfessor Su Seok Choi’s teamsound integration in displays
