Fact-checked by Grok 2 weeks ago

High-resolution audio

High-resolution audio, commonly abbreviated as Hi-Res Audio, is a category of digital audio formats and systems designed to deliver superior sound fidelity compared to standard (CD) quality, which is limited to a sampling rate of 44.1 kHz and 16-bit depth. It encompasses lossless audio encodings that capture a broader frequency spectrum—often extending beyond 20 kHz—and provide greater , typically achieved through sampling rates greater than 44.1 kHz and/or bit depths greater than 16 bits, enabling more precise reproduction of the original recording as intended by artists and engineers. The technical foundation of high-resolution audio builds on the Nyquist-Shannon sampling theorem, which posits that audio signals must be sampled at least twice the highest frequency to avoid ; while audio covers the human up to approximately 20 kHz, Hi-Res formats extend this to kHz or beyond (e.g., 96 kHz or 192 kHz), potentially preserving ultrasonic content and reducing quantization noise for enhanced clarity and spatial imaging. Bit depths exceeding 16 bits—such as 24 bits—offer a of up to 144 dB, compared to 's 96 dB, minimizing audible distortion in quiet passages and providing headroom for professional mastering. Common formats include uncompressed options like and AIFF, as well as lossless compressed codecs such as and ALAC, with specialized high-resolution variants like DSD () used in Super Audio CDs (SACD) that employ 1-bit at rates up to 2.8224 MHz. Development of high-resolution audio traces back to the late with research into extended and in professional recording, evolving into consumer availability by the late 1990s and early 2000s through formats like and SACD. A pivotal standardization effort occurred in 2014, when the (RIAA), (CTA), Digital Entertainment Group (DEG), and the Producers & Engineers Wing of established criteria for Hi-Res certification, including the "Hi-Res MUSIC" logo to identify qualifying downloads and streams. Adoption has grown with streaming services like and offering Hi-Res tiers, alongside hardware support from devices certified by the Audio Society and others, though file sizes are significantly larger—often 4-10 times that of CD-quality MP3s—necessitating robust storage and . Proponents argue that high-resolution audio yields perceptible benefits, such as improved , reduced inter-sample peaks, and a more natural soundstage, with listener tests demonstrating audible differences in controlled environments. However, the field remains contentious; meta-analyses of perceptual studies indicate that while some trained listeners discern advantages in and high-frequency detail, many cannot reliably distinguish Hi-Res from CD-quality audio under blind conditions, raising questions about the necessity for casual consumers amid the prevalence of lossy formats like . Despite this, high-resolution audio has become integral to markets, professional studios, and archival preservation, driving innovations in playback equipment and content delivery.

Definitions and Fundamentals

Definition and Scope

High-resolution audio refers to formats whose sampling rates and bit depths exceed those of the standard, defined as 44.1 kHz sampling rate and 16-bit depth. Typically, these formats employ a 24-bit depth and sampling rates greater than 44.1 kHz, such as 96 kHz or 192 kHz, to capture and reproduce with enhanced fidelity. Industry certifications, such as the RIAA's Hi-Res MUSIC logo, specify minimums of 48 kHz sampling rate and 20-bit depth (or equivalent in DSD) for qualifying content. The scope of high-resolution audio includes studio that preserve the original production quality from the mixing stage, often delivered via techniques like or ALAC to retain all audio data without degradation. It applies across music production for precise and mixing, audio archiving to safeguard detailed source material for long-term preservation, and consumer listening through premium downloads and streaming services that support superior playback. Key intended benefits encompass an expanded for handling subtle nuances and intense peaks, extended beyond the 20 kHz human hearing limit, up to 48 kHz or 96 kHz depending on sampling rate, to potentially enable more natural sound reproduction by capturing ultrasonic content, and minimized quantization noise for cleaner . In contrast to standard audio, which provides approximately 96 of dynamic range at 16-bit depth, high-resolution formats at 24-bit depth achieve about 144 , offering substantially greater headroom and reduced .

Technical Specifications

High-resolution audio is defined by technical parameters that exceed the standard quality of 44.1 kHz sampling rate and 16-bit depth, aiming to capture and reproduce audio signals with greater . The Nyquist-Shannon sampling theorem forms the foundational principle for representation, stating that a continuous-time signal can be perfectly reconstructed from its samples if the sampling frequency f_s is greater than twice the highest frequency component f_{\max} in the signal, expressed as f_s > 2 f_{\max}. This condition prevents , where higher frequencies masquerade as lower ones, distorting the audio. In high-resolution audio, sampling rates often reach 96 kHz or 192 kHz, allowing capture of frequencies up to 48 kHz or 96 kHz, respectively, far beyond the typical human hearing range of 20 Hz to 20 kHz. Bit depth determines the precision of amplitude quantization in digital audio, directly influencing the dynamic range—the span between the quietest and loudest sounds without distortion or noise overpowering the signal. The theoretical dynamic range for an n-bit quantized signal is approximated by the formula: \text{Dynamic Range} \approx 6.02n + 1.76 \, \text{dB} This derives from the quantization noise power being uniformly distributed across the signal bandwidth, with each additional bit providing roughly 6 dB of range improvement. For instance, 24-bit depth yields approximately 144 dB dynamic range, enabling subtle details in quiet passages to be preserved without audible quantization artifacts, in contrast to the 96 dB of 16-bit audio. Frequency response in high-resolution audio extends beyond the 20 kHz limit of human audition to include ultrasonic content above 20 kHz, potentially up to 96 kHz or higher depending on the sampling rate. This extension accommodates and effects in instruments like cymbals or violins, where measurable energy persists into the ultrasonic range, though its perceptual benefits remain debated. Such capabilities support applications in professional recording and mastering, where preserving full-spectrum content aids in nonlinear processing without introducing audible artifacts. High-resolution setups achieve superior (SNR) through increased and sampling rates, with SNR improvements scaling by about 3 per octave of in delta-sigma converters, enhancing noise shaping to push quantization noise into inaudible ultrasonic bands. (THD) is also reduced, often to below 0.001% in modern digital-to-analog converters (DACs), as higher sampling rates minimize nonlinearities in reconstruction filters and allow for gentler analog slopes. These metrics collectively enable cleaner reproduction, with SNR exceeding 120 and THD+N under -100 in premium high-res systems. Unlike (PCM), which quantizes amplitude levels at fixed intervals, (DSD) employs (PDM), a 1-bit encoding scheme where signal amplitude is represented by the density of pulses in a high-frequency , typically at 2.8224 MHz for DSD64. PDM contrasts with PCM by avoiding multi-bit quantization, instead using and noise shaping to achieve effective resolutions comparable to 24-bit PCM, with lower in-band noise but higher overall data rates; for example, DSD's noise is shifted to ultrasonic frequencies, simplifying analog filtering. This approach is particularly suited for high-resolution formats like , offering theoretical dynamic ranges over 120 within the audible band.

Historical Development

Origins and Early Innovations

The foundations of high-resolution audio trace back to advancements in analog during the mid-20th century, which enabled greater and complexity in sound capture. In the 1950s, early multitrack systems emerged with two- to four-track tape recorders, allowing engineers to layer instruments and vocals separately for enhanced clarity and over recordings. By the late 1960s and into the 1970s, technology progressed to eight-track machines, as exemplified by ' adoption at in 1968 for albums like the White Album, where they utilized the format to experiment with intricate overdubs and spatial effects. The arrival of 24-track analog recorders in the early 1970s, such as the Studer A80 and models on 2-inch tape, further elevated professional production standards, providing expansive headroom and reduced noise for capturing orchestral and rock ensembles with unprecedented detail. Transitioning to digital prototypes in the late 1970s and early 1980s marked a pivotal shift toward high-resolution audio, driven by (PCM) systems that digitized analog signals at higher sampling rates for superior accuracy. Denon's DN-023R, introduced in 1972, represented an early milestone as an eight-channel digital recorder operating at 47.25 kHz with 13-bit resolution, used to capture classical performances like the Smetana Quartet's rendition of Mozart's works, demonstrating reduced distortion and wider frequency response compared to analog tape. Sony's PCM-F1, released in 1981, brought portable consumer-level to market by encoding audio onto VCR tapes at 44.056 kHz and 16-bit depth, allowing hobbyists and professionals to preserve broadcasts and live sessions with minimal noise and high fidelity, thus popularizing PCM technology beyond studios. These innovations profoundly influenced professional audio sectors, particularly in soundtracks and preservation, where demands for immersive and archival-quality sound spurred further refinement. In cinema, precursors to advanced spatial systems like appeared through Dolby Stereo's introduction in the mid-1970s, which encoded four channels (including surround) onto optical prints for films such as Star Wars (1977), enhancing and localization to create more lifelike audio environments. For archiving, 1970s analog multitrack techniques on high-quality tape, combined with early digital experiments like Denon's, enabled institutions to store performances with extended —up to 20 kHz—and low noise floors, preserving nuances in symphonic works that traditional formats obscured. Key figures and proposals in the bridged these developments toward consumer high-resolution formats, emphasizing cinema-derived standards for home use. Audio engineer , founder of the system in 1983 at , advanced high-fidelity reproduction by certifying theaters and equipment for consistent low-distortion playback across wide bandwidths, influencing the push for higher sampling rates in digital media. Early initiatives, proposed in the mid-1990s by consortia including and , aimed to deliver multichannel audio at up to 24-bit/192 kHz on optical discs, building on PCM prototypes to enable lossless archiving of professional masters for audiophiles.

Standardization and Adoption

The standardization of high-resolution audio began to take shape in the early 2000s, with key milestones establishing technical benchmarks and certification programs. In 2014, the Audio Society (JAS) announced the official definition of Hi-Res Audio and introduced the Hi-Res Audio logo to certify products capable of reproducing audio at sampling rates of 96 kHz or higher and bit depths of 24 bits or greater, surpassing CD-quality specifications. This initiative was later adopted internationally through collaborations, such as with the Consumer Electronics Association (CEA) in the United States, to promote consistent labeling and consumer awareness of high-resolution capabilities. Complementing this, the (AES) standards like AES10 support interchange up to 96 kHz sampling and 24-bit resolution for professional applications. These efforts provided a framework for across devices and media. Adoption of high-resolution audio accelerated in the mid-2000s through integration into emerging media formats and . The launch of Blu-ray Disc in 2006 marked an early widespread adoption phase, enabling lossless high-resolution audio tracks via codecs like and , which support up to 24-bit/192 kHz multichannel playback, thus extending studio-quality sound to home theater systems. By the , high-resolution audio permeated mobile devices, exemplified by LG's introduction of a Hi-Fi Quad DAC in its 2015 V10 smartphone, which delivered 24-bit/192 kHz playback directly to wired , bridging professional-grade audio with portable consumption. This period also saw growth within communities, where dedicated forums and events fostered demand for certified equipment and content, driving broader ecosystem development. Market drivers for high-resolution audio's expansion included the ongoing decline of sales, which fell sharply from the early 2000s onward, prompting a shift toward channels capable of delivering uncompressed or lossless high-resolution files. This transition encouraged platforms and labels to prioritize high-resolution offerings, reflecting increasing consumer interest in premium experiences. As of 2023, the high-resolution audio was valued at approximately $32.8 billion, projected to reach $78 billion by 2030, driven by advancements in streaming and . However, adoption remained uneven, particularly among audiophiles, due to and content availability barriers. A notable divide exists between professional and consumer sectors in high-resolution audio adoption. In recording studios, 96 kHz/24-bit has become a for production workflows, offering enhanced headroom for editing, processing, and pitch correction while minimizing artifacts during downsampling to delivery formats. In contrast, consumer uptake has been slower, hampered by higher costs for compatible hardware, limited high-resolution content libraries, and the prevalence of compressed streaming services, resulting in high-resolution playback remaining niche outside dedicated markets.

Formats and Encoding

Audio File Formats

High-resolution audio relies on several digital file formats that preserve or enhance audio fidelity beyond standard quality (16-bit/44.1 kHz). These formats primarily use or specialized encoding to maintain the integrity of high-bit-depth and high-sample-rate signals, enabling resolutions up to 24-bit/192 kHz or beyond. Lossless formats ensure bit-perfect reproduction of the original PCM data, while others like DSD offer alternative schemes for perceived analog-like reproduction. Among the most widely adopted lossless PCM-based formats is (Free Lossless Audio Codec), an open-source standard developed by the that achieves , reducing storage needs without data loss. FLAC supports multi-channel audio and tagging, making it ideal for archiving and distribution of high-resolution tracks, such as 24-bit/96 kHz recordings. Similarly, (Apple Lossless Audio Codec) provides comparable for PCM data, supporting up to 32-bit depth and 384 kHz sample rates, and is natively integrated into Apple's ecosystem for seamless playback on and macOS devices. (Waveform Audio File Format), an uncompressed PCM container developed by and , serves as a baseline for professional workflows, storing raw high-resolution audio without any encoding artifacts but at full file size. DSD (Direct Stream Digital) represents a distinct approach, employing 1-bit encoding at 2.8224 MHz (DSD64) using to create a pulse-density stream that mimics analog waveforms, with higher rates such as DSD128 (5.6448 MHz) and DSD256 (11.2896 MHz) commonly used for extended ; originally designed for (SACD) media. This format prioritizes high-frequency response up to 100 kHz and is favored in circles for its purported natural , though it requires specialized conversion for PCM-based systems. Other notable formats include (Monkey's Audio), a lossless that demands more computational resources for encoding and decoding. (Master Quality Authenticated) combines lossless and lossy elements through perceptual coding to fold high-resolution details into smaller files compatible with standard playback, authenticating studio masters; however, it has faced controversies over its non-fully lossless nature and added processing artifacts. These formats carry significant file size implications for high-resolution content; for instance, a 24-bit/96 kHz file is approximately 9 times larger than a CD-quality 320 kbps for the same duration, reflecting the increased data demands of higher sampling and bit depths.

Sampling and Bit Depth Standards

High-resolution audio standards emphasize sampling rates and bit depths that extend beyond the specifications of 44.1 kHz and 16 bits, enabling greater and . These parameters determine the audio's and (SNR), with industry consensus defining high-resolution as formats providing a bandwidth exceeding 20 kHz and an SNR greater than 96 dB to capture nuances beyond standard CD capabilities. Sampling rate tiers in high-resolution audio are structured to balance audio fidelity, , and practical use. The 48 kHz rate serves as a foundational standard for professional recording, processing, and video , offering a of 24 kHz. Common high-resolution rates include 88.2 kHz and 96 kHz, which double the rate for improved and reduced artifacts. Ultra-high rates such as 176.4 kHz and 192 kHz support even broader bandwidths up to approximately 96 kHz, while extreme rates like 384 kHz are used in specialized production for maximum resolution, though they demand significant computational resources. The () recommends 48 kHz as the preferred frequency for interchange, with higher multiples adopted for high-resolution workflows. Bit depth standards focus on enhancing dynamic range and reducing quantization noise. Early high-resolution formats utilized 20-bit depth, providing an SNR of about 120 , but 24-bit has become the AES-recommended norm for distribution, delivering up to 144 dynamic range for capturing subtle details in quiet passages. In production and editing, 32-bit floating-point formats are standard to preserve headroom and prevent clipping during processing, though they are typically down-converted to 24-bit for final delivery. The (RIAA) specifies high-resolution music as requiring at least 20-bit depth at 48 kHz or higher to reproduce the full spectrum from superior masterings. Compatibility challenges arise in playback systems, where upsampling lower-rate content to match high-resolution DAC capabilities can introduce artifacts, though native playback of high-resolution files preserves original . For (DSD) formats, which use a 1-bit, high-rate stream (e.g., 2.8224 MHz for DSD64), conversion to PCM is often necessary for non-native devices; recommended standards involve to equivalent PCM resolutions like 24-bit/88.2 kHz or 352.8 kHz/24-bit (DXD) to maintain resolution during editing and playback. The (EBU) contributes to interface standards supporting these conversions, ensuring interoperability in professional environments.

Playback and Equipment

Required Hardware

To accurately reproduce high-resolution audio, which typically involves sampling rates beyond 48 kHz and bit depths exceeding 16 bits, the demands components capable of handling elevated data throughput while minimizing and . The (DAC) serves as the core element, converting high-bit-depth digital streams into analog signals with fidelity. Chips like ESS Technology's Sabre series support up to 32-bit resolution and 384 kHz sampling rates, allowing for the capture of frequencies up to 192 kHz and dynamic ranges over 120 dB. Similarly, AKM's AK4490REQ DAC employs 32-bit processing and accommodates PCM up to 768 kHz, leveraging VELVETSOUND architecture to achieve a (SNR) of 120 dB in stereo mode. To address —subtle timing variations from source clocks that can introduce artifacts—many high-end DACs integrate asynchronous (ASRC), which decouples the input stream from the DAC's master clock, attenuating jitter to below audible thresholds while preserving phase accuracy. Amplification and transduction hardware must match this precision to avoid introducing coloration or limiting headroom. Amplifiers with , such as the MX-HPA boasting an SNR exceeding 120 dB A-weighted, ensure that quiet passages remain unmasked by electronic hiss, supporting the wide dynamic swings inherent in high-res formats. For output devices, planar magnetic drivers offer superior and extended ; the HiFiMan Susvara, for instance, utilizes nanoscale planar diaphragms to deliver a from 6 Hz to 75 kHz, enabling reproduction of harmonic overtones and spatial cues beyond standard limits. These drivers reduce in the audible range while handling the increased power demands of high-bit-depth signals without . Storage solutions are essential given the substantial file sizes of high-res audio—a 24-bit/192 kHz requires approximately 70 per minute, far surpassing the 10 MB per minute of CD-quality files—necessitating high-capacity solid-state drives (SSDs) or mechanical hard disk drives (HDDs) in the multi-terabyte range for libraries of even modest duration. For signal transport from storage to DAC, USB or audio interfaces with are recommended to eliminate ground-loop interference; the Gustard U18, for example, provides while transmitting PCM up to 768 kHz and DSD512 without . Finally, interconnection cables play a critical role in maintaining ; balanced XLR connections employ differential signaling to reject common-mode noise, effectively lowering the by up to 60 dB compared to unbalanced links in longer runs or noisy environments. As of 2025, many consumer devices, including flagship smartphones and portable players (DAPs), offer native support for high-resolution audio playback up to 24-bit/192 kHz via integrated DACs or connectivity, broadening accessibility beyond dedicated high-end setups.

Software and

Software for high-resolution audio playback emphasizes bit-perfect output to preserve the original sampling rates and bit depths without alteration by the operating system. Audirvāna Studio provides dedicated support for high-resolution formats through its exclusive core player, which delivers intact audio data directly to the (DAC) via protocols like WASAPI on Windows and integer-mode playback on macOS, ensuring no resampling or mixing occurs during playback of files up to 32-bit/768 kHz PCM and DSD512. Roon's audio engine similarly enables bit-perfect reproduction of high-resolution content, including PCM up to 32-bit/768 kHz and DSD up to DSD512 in or multichannel configurations, by adjusting output to match the connected hardware without introducing processing artifacts. achieves comparable fidelity using WASAPI in exclusive mode or drivers, which bypass the Windows audio mixer to support native high-resolution playback, such as 24-bit/192 kHz, when paired with compatible components like the official WASAPI output . Editing tools for high-resolution workflows must handle elevated bit depths and sample rates throughout recording, mixing, and rendering processes. supports sample rates from 6,000 Hz to 192,000 Hz and bit depths up to 32-bit floating point, allowing users to import, edit, and export 24-bit/192 kHz files without mandatory conversion, though capabilities determine the actual recording . DAW facilitates 24-bit/192 kHz workflows with its 64-bit internal processing engine, enabling seamless handling of high-resolution audio from import to final render, including support for virtually any or sample rate compatible with the user's audio interface. Compatibility challenges arise primarily from operating system audio subsystems that impose resampling or bit-depth limitations on high-resolution signals. On Windows, the (UAC) and default audio engine route playback through a software mixer that resamples all content to the system's fixed rate—often 48 kHz—potentially degrading 24-bit/192 kHz files unless exclusive-mode drivers like WASAPI are employed to send unaltered data directly to the DAC. Mobile platforms present similar issues, but apps like Neutron Music Player address them on by earning Hi-Res Audio certification, supporting output up to 32-bit/1.536 MHz PCM and DSD1024 to USB DACs or dedicated audio players without truncation or resampling when hardware permits. Plugin ecosystems extend high-resolution capabilities in digital audio workstations (DAWs) by allowing effects processing at native sample rates. VST3 plugins, as defined by the specification, operate at the host DAW's sample rate without inherent downsampling, enabling high-resolution workflows up to 192 kHz or beyond for tasks like equalization and dynamics when the session is set accordingly. Similarly, Apple's (AU) format integrates with macOS to process high-resolution signals—such as 24-bit/192 kHz—natively in compatible hosts like , avoiding bit-depth reduction or resampling during real-time effects application.

Distribution and Accessibility

Streaming Platforms

Several major streaming platforms have emerged as leaders in delivering high-resolution audio, offering lossless formats that exceed quality (16-bit/44.1 kHz) to provide greater and for audiophiles. These services typically stream in formats like , supporting bit depths and sample rates that capture studio-master fidelity, often integrated with compatible hardware such as digital-to-analog converters (DACs). Key players include , , , and Unlimited, each with distinct technical capabilities and ecosystem integrations. Tidal provides high-resolution streaming through its HiRes FLAC format, supporting up to 24-bit/192 kHz for superior sound quality in stereo playback. Qobuz specializes in lossless hi-res audio, delivering 24-bit resolution at sample rates from 44.1 kHz to 192 kHz, emphasizing editorial curation alongside technical purity. Apple Music introduced hi-res lossless audio in 2021, offering streams up to 24-bit/192 kHz across its catalog without additional cost to subscribers. Amazon Music Unlimited's Ultra HD tier extends to 24-bit/192 kHz, providing lossless audio that is up to 10 times the quality of standard streams, with an average bitrate of around 3,730 kbps for these tracks.
PlatformHi-Res SpecsCatalog Size (Total Tracks)Subscription Pricing (Individual, USD/month)
24-bit/192 kHz (HiRes FLAC)110 million+$10.99
24-bit/192 kHz ()100 million+$12.99 (Studio tier)
24-bit/192 kHz (ALAC)100 million+$10.99
Amazon Music Unlimited24-bit/192 kHz ()100 million+ (7 million+ in Ultra HD)$10.99
These platforms operate on subscription models with premium tiers ranging from $10 to $20 per month, often including or discounts, while maintaining vast catalogs with millions of tracks available in hi-res. Business models focus on ad-free access, artist royalties, and exclusive content, with hi-res comprising a growing portion of offerings—such as over 7 million Ultra tracks on . High-resolution streaming demands significant , typically 9-10 Mbps for 24-bit/192 kHz tracks, though spatial audio modes typically require around 1 Mbps or less due to , despite multi-channel encoding. Services often employ to adjust quality based on connection stability, falling back to lower resolutions if needed, while fixed hi-res modes ensure maximum on stable networks. Innovations in these platforms include offline high-res downloads, allowing users to cache 24-bit/192 kHz files for playback without , preserving quality on compatible devices. Additionally, spatial audio extensions like integrate with hi-res streams, creating immersive, object-based soundscapes—supported on , , and Unlimited for tracks mixed in up to 7.1.4 channels. This enhances the listening experience on or home systems, though it requires specific hardware decoding.

Physical Media and Downloads

High-resolution audio content is distributed through digital download stores that provide permanent ownership of files in lossless formats such as and , often at sampling rates of 96 kHz or higher and bit depths of 24 bits. HDtracks, launched in 2007, specializes in these downloads, offering albums from major and independent labels in resolutions up to 24-bit/192 kHz, with prices typically ranging from $15 to $30 per album depending on the content and quality tier. Similarly, 7digital provides hi-res files at 24-bit/96 kHz across a catalog exceeding 30 million tracks, with album prices around $10 to $20, emphasizing DRM-free access for audiophiles seeking better-than-CD quality. enables artists to upload and sell high-res options directly, supporting 24-bit or downloads at user-set prices, often $10 to $20 per album, allowing for flexible, artist-driven distribution of studio masters. Physical media for high-resolution audio includes specialized formats designed for superior fidelity beyond standard CDs. The (SACD), introduced by and in 1999, employs (DSD) encoding at a 2.8224 MHz sampling rate with 1-bit depth, enabling playback of multi-channel and stereo high-res content on hybrid discs compatible with conventional CD players. HQCD, developed by Memory-Tech in the late , enhances standard CD audio through a proprietary substrate with improved transparency, reducing jitter and improving for subtly higher playback quality. Audiophile vinyl reissues, such as 180-gram pressings from labels like Impex Records, are often cut from high-resolution digital masters recaptured at 24-bit/96 kHz or better, preserving analog warmth while leveraging modern mastering techniques for enhanced . In archival contexts, institutions like the digitize historical analog recordings to 96 kHz/24-bit files for long-term preservation, ensuring high-fidelity transfers that capture nuances lost in lower-resolution formats and support future access without generational degradation. Despite an overall decline in sales—representing 10% of U.S. as of the first half of 2025—high-resolution formats sustain demand among niche communities valuing tangible ownership and superior soundstaging. Alternative delivery methods include USB flash drives for custom high-res file bundles, capable of storing hundreds of albums in capacities up to 128 GB, and Blu-ray discs for high-capacity audio-only releases supporting up to 24-bit/192 kHz PCM or DSD layers.

Debates and Criticisms

Scientific Perspectives

Scientific research on the perceptual benefits of high-resolution audio, defined as formats exceeding 16-bit/44.1 kHz sampling, has primarily focused on controlled listening tests to determine audibility thresholds. A seminal double-blind study by Meyer and Moran in 2007 examined the audibility of inserting a CD-standard analog-to-digital-to-analog (A/D/A) loop into high-resolution playback chains using (SACD) and sources. The tests involved about 60 participants, including trained audio professionals, who failed to distinguish the looped CD-quality signal from the native high-resolution versions in hundreds of trials, with performance at chance levels (50% correct identification). This suggests that for most listeners, differences between high-resolution and standard CD audio are inaudible under typical conditions. Psychoacoustic principles underpin these findings, as human hearing is limited to frequencies roughly between 20 Hz and 20 kHz, with a spanning approximately 120 from the of hearing to the pain . These limits imply that content beyond 20 kHz, often present in high-resolution formats, is not directly audible and primarily contributes to spatial through potential effects rather than explicit . Similarly, quantization noise in 16-bit audio yields a signal-to- ratio (SNR) of about 96 , which falls below typical audibility thresholds of -90 or lower in the presence of masking sounds, rendering such imperceptible during normal playback. Placebo effects can influence subjective high-resolution preferences, as expectation biases have been noted in non-blinded evaluations, but double-blind protocols mitigate this. A 2016 meta-analysis by Reiss synthesized 18 perceptual studies involving over 400 participants and 12,500 trials, revealing a small but statistically significant to discriminate high-resolution audio from standard formats, with an increasing notably for trained listeners ( of 1.43 for detection). However, the overall discrimination rate remained low (52.6% correct), indicating subtle benefits confined to specific scenarios like quiet environments and familiar material. Studies through 2016 confirm that while trained individuals may perceive marginal improvements in or spatial cues in ideal conditions, the advantages are not robust for the general population and often fall within psychoacoustic masking limits.

Marketing and Consumer Implications

High-resolution audio is frequently marketed by the recording industry and manufacturers as a premium format offering superior fidelity and immersion compared to standard CD-quality audio, often through standardized s and certifications. The Japan Audio Society (JAS) introduced the Hi-Res AUDIO in 2014 to certify devices and content capable of reproducing audio beyond 16-bit/44.1 kHz, emphasizing its role in delivering "authentic sound" that captures the nuances of studio masters. Similarly, the (RIAA) launched the Hi-Res MUSIC in 2015 to help consumers identify lossless digital files exceeding CD specifications, positioning high-resolution formats as essential for audiophiles seeking the "highest-quality" listening experience. These branding efforts have driven premium pricing, with hi-res downloads and streaming subscriptions typically costing 20-50% more than standard options, and compatible hardware like DACs and often commanding higher prices due to certification requirements. Consumer adoption of high-resolution audio has grown steadily, fueled by marketing campaigns highlighting its emotional and technical benefits, though accessibility remains limited by cost and compatibility. A 2021 survey found that 52% of respondents actively seek high-resolution or lossless audio, reflecting a shift toward quality-driven purchases amid the rise of wireless earbuds and smart speakers supporting hi-res playback. However, this enthusiasm is tempered by practical implications: hi-res files require significantly more storage (up to six times that of CD-quality) and bandwidth, increasing costs for downloads and data usage, while not all playback devices can fully utilize the format without downsampling, leading to potential buyer confusion between true hi-res and merely lossless compression. By 2025, major platforms like Apple Music and Amazon Music have expanded hi-res and lossless offerings, contributing to broader adoption despite ongoing debates. Criticisms of high-resolution audio marketing center on claims of exaggerated benefits and pseudoscientific hype, potentially misleading consumers into unnecessary expenditures. Audio codec developers at Xiph.Org argue that 24-bit/192 kHz formats offer no audible improvements over 16-bit/44.1 kHz, as human hearing is limited to 20 Hz–20 kHz with a far below 24-bit capabilities, and high sample rates can introduce ultrasonic artifacts that degrade playback fidelity. They describe hi-res promotion—exemplified by campaigns from artists like —as a "magic bullet" exploiting consumer desire for "better" without addressing core issues like poor mastering, resulting in wasted resources on larger files and overpriced gear. Conversely, perceptual studies provide a nuanced view: a 2016 meta-analysis of 18 experiments involving over 400 participants and 12,500 trials found that listeners could detect small but statistically significant quality improvements in high-resolution audio (e.g., 24-bit/96 kHz) over standard in blind tests, with an average preference rate indicating subtle advantages in clarity and realism. This suggests marketing claims have some basis, though the benefits may be imperceptible to many casual listeners without high-end equipment, raising implications for informed consumer choices in a blending genuine with hype.

References

  1. [1]
    AES Technical Committee » High Resolution Audio
    High resolution refers to extended resolution in bandwidth, dynamic range, time, and spatial acuity. The achievement of excellent resolution within audio ...Missing: definition | Show results with:definition
  2. [2]
    High Resolution Audio Initiative Gets Major Boost with New “Hi-Res ...
    Jun 23, 2015 · High Resolution Music is officially defined as “lossless audio capable of reproducing the full spectrum of sound from recordings which have ...
  3. [3]
    https://www.aes.org/e-lib/browse.cfm?elib=18296
  4. [4]
    https://benchmarkmedia.com/blogs/application_notes/14949345-high-resolution-audio-bit-depth
  5. [5]
    High-Res Audio, DSD Audio - NativeDSD Music
    These are the six audio file formats that can be referred to as “High Resolution Audio”: DSD (dff), DSD (dsf), WAV, AIFF, FLAC, and ALAC. At the NativeDSD ...
  6. [6]
    (PDF) High-Resolution Audio: A History and Perspective
    This review covers the history of the period, focusing on the main directions that drove experimentation and development up to the present.
  7. [7]
    HI-RES MUSIC INITIATIVE EXPANDS TO INCLUDE MUSIC ... - RIAA
    May 11, 2016 · These technologies ensure that the listener hears music that preserves, without loss of information, recordings from sources that achieve a ...
  8. [8]
    AES News » Research Finds Audible Differences with High ...
    Jul 11, 2016 · Listeners can hear a difference between standard audio and better-than-CD quality, known as high-resolution audio, according to a new study.Missing: criticisms | Show results with:criticisms
  9. [9]
    A Meta-Analysis of High Resolution Audio Perceptual Evaluation
    High resolution audio may be loosely defined as those systems and formats that are capable of rendering beyond standard quality audio, i.e., more than 16 bits, ...
  10. [10]
    [PDF] 2014 Trends in High Resolution Audio
    Growth in high resolution audio (HRA) over the last several years has been robust. HRA is an established mainstay in the professional and audiophile markets ...
  11. [11]
    High-Resolution Audio - AES
    “High-resolution audio” is that group of digital formats whose sampling rates and bit depths exceed those of the CD (44.1 kHz and 16 bits).
  12. [12]
    What is high-resolution audio? And is hi-res music worth it?
    Oct 17, 2025 · They include the popular FLAC (Free Lossless Audio Codec) and ALAC (Apple Lossless Audio Codec) formats, both of which are compressed but in a ...
  13. [13]
    About ProStudioMasters
    Sep 24, 2013 · ProStudioMasters offers music audio downloads available in uncompressed AIFF, DSD and lossless FLAC formats in resolutions up to 384 kHz / 24- ...Missing: scope applications
  14. [14]
    Introduction | HIGHRESAUDIO
    High resolution audio uses lossless compression to save disc space (e.g. FLAC or ALAC). The screenshot of the MusicScope-Measurement shows a perfectly levelled ...Missing: scope | Show results with:scope
  15. [15]
    Producers and Engineers Wing Technical Guidelines
    Recommendations for Hi-Res Music Production · Recommendation for Delivery of Recorded Music Projects · Folder Definitions · Folder Hierarchy & Naming. Crediting ...
  16. [16]
    https://www.recordingacademy.com/producers-engineers-wing/technical-guidelines
  17. [17]
    Audio Bit Depth: Everything you need to know - SoundGuys
    Dec 17, 2024 · Summary: 16-bit vs 24-bit Audio at a Glance ; Dynamic Range. 16-bit: 96dB (roughly CD quality); 24-bit: 144dB (professional recording headroom).<|control11|><|separator|>
  18. [18]
    What Is the Nyquist Theorem - MATLAB & Simulink - MathWorks
    Without the Nyquist theorem, the transition from analog to digital processing would be prone to errors, such as aliasing. Aliasing causes different signals to ...<|control11|><|separator|>
  19. [19]
    Nyquist Sampling Theorem - GeeksforGeeks
    Jul 23, 2025 · Preventing Aliasing: When the Sampling rate is double the highest frequency of the signal, Aliasing can be avoided. Aliasing occurs when the ...How Nyquist Sampling Theorem... · Aliasing In Nyquist Theorem · Applications Of Nyquist...
  20. [20]
    [PDF] MT-001: Taking the Mystery out of the Infamous Formula,"SNR ...
    SNR = 6.02N + 1.76dB, over the dc to fs/2 bandwidth. Eq. 9. Bennett's paper shows that although the actual spectrum of the quantization noise is quite.Missing: depth dynamic audio
  21. [21]
    [PDF] Increasing the Dynamic Range and SNR of Audio ADC With ...
    ... N-bit ADC can be expressed as. SNR = 6.02N + 1.76 dB. (1). Where N is the number of bits. By oversampling, the SNR can be increased and a designer can quantify ...Missing: formula | Show results with:formula
  22. [22]
    High-frequency sound components of high-resolution audio are not ...
    Dec 10, 2020 · One common belief is that high-resolution digital audio is superior due to the higher frequency (> 22 kHz) of its sound components, a ...<|control11|><|separator|>
  23. [23]
    There's Music Above 20 kHz! - Real HD-Audio
    Feb 17, 2014 · The proportion of energy above 20 kHz is, for the muted trumpet, 2 percent; violin, 0.04 percent; oboe, 0.01 percent; and cymbals, 40 percent.
  24. [24]
    [PDF] High-definition audio is changing the way we listen
    The lower the THD, the better the audio performance. • Noise and signal-to-noise (SNR) ratio – this is the amount of noise or the ratio of signal to noise that ...
  25. [25]
    Total Harmonic Distortion vs. THD+N - Audio Precision
    Aug 28, 2019 · THD and THD+N are acronyms for Total Harmonic Distortion and Total Harmonic Distortion Plus Noise. Both are measures of harmonic distortion.
  26. [26]
    One-bit Delta Sigma Audio Encoding (DSD), Direct Stream Digital
    Apr 26, 2024 · Format Description for DSD -- System for recreating audible signals using pulse-density modulation encoding known as Direct Stream Digital; ...
  27. [27]
    https://ieeexplore.ieee.org/document/1158788
  28. [28]
    Music Technology of the 1970s: A Timeline | Pitchfork
    Aug 25, 2016 · As late as 1966, the Beatles recorded Revolver on a four-track machine; they didn't use eight-track recording until 1968. By 1970, 16 tracks ...
  29. [29]
    https://www.uaudio.com/blogs/ua/analog-tape-recording-basics
  30. [30]
    How the Beatles Took Recording Technology to a New Level in ...
    Oct 2, 2019 · The synthesizer ended up being used in three other tracks on the album: “Here Comes the Sun,” “Maxwell's Silver Hammer” and “I Want You (She's ...
  31. [31]
    [PDF] The Dawn of Commercial Digital Recording
    PCM-to-VCR adapters such as the Sony PCM-F1 (introduced in 1981). Around the same time NHK was perfecting the stereo PCM audio recorder, the. British ...
  32. [32]
    Development of Digital Audio Technology
    By 1972 Denon had developed its own digital recording system: the DN-023R with 8 channels, 47.25kHz and 13bit, with which the Smetana Quartet and Mozart's ...
  33. [33]
    The Extraordinary Evolution of Sony Digital Audio Processors
    Aug 18, 2024 · The portable Sony PCM-F1​​ Building on the success of the Sony PCM-1, Sony released the Sony PCM-F1 in 1981. The Sony PCM-F1 was designed to be ...
  34. [34]
    The Technologies Which Shaped Modern Surround Sound
    Jan 24, 2024 · In 1976 Dolby introduced a noise reduction system designed for six track 70mm film prints. In this system, the speaker configuration from a ...
  35. [35]
    The Evolution of Sound in Film: From Silent Movies to Dolby Surround
    Mar 12, 2025 · Then came the game-changer: Dolby Stereo, introduced in the 1970s. George Lucas's Star Wars (1977) was one of the first films to use this new ...
  36. [36]
    Tomlinson Holman Interview | Life, Career, and the Future of Sound
    Tomlinson Holman is a film theorist, audio engineer, and inventor of film technologies, notably the Lucasfilm THX sound system. He also worked on Star Wars ...Missing: DVD- proposals resolution
  37. [37]
    The History of DVD | Stewart Wolpin
    Sep 24, 2015 · In 1990, Lieberfarb formed a collaboration with Philips on a next-generation disc format, but was unimpressed with Philips' MPEG-1 efforts. In ...
  38. [38]
    Japan Audio Society | Hi-Res Audio Logo - 日本オーディオ協会
    Definition of Hi-Res Audio (Announced on June 12th 2014)Updated on November 9th , 2022 ... Hi-Res Audio logo applicable or Hi-Res Audio Wireless logo applicable.
  39. [39]
    CEA, Japan Audio Society In High-Res Collaboration - Twice
    Dec 18, 2014 · Arlington, Va. – The Consumer Electronics Association (CEA) will make the High-Resolution Audio (HRA) logo developed by the Japan Audio Society ...
  40. [40]
    AES Standard » AES10-2020 - Audio Engineering Society
    ... represented digital audio data at a common sampling frequency within the range 32 kHz to 96 kHz, having a resolution of up to 24 bits per channel. The format
  41. [41]
    LG TO DELIVER HI-FI MUSIC TO PREMIUM SMARTPHONE ...
    Aug 13, 2015 · Hi-Fi music delivers audio quality very close to the original sound with playback of 24bit/192kHz, about six times richer and clearer than the ...
  42. [42]
    Oppenheimer and the resurgence of Blu-ray and DVDs - BBC
    Jan 3, 2024 · "While it's true that physical media continues to decline as consumers embrace digital formats, we do see high-profile theatrical new ...<|separator|>
  43. [43]
    High-resolution Audio Market Size, Share, Growth | CAGR Forecast ...
    Rating 4.6 (82) High-resolution Audio Market size was valued at USD 13750 million in 2024 and the revenue is expected to grow at a CAGR of 8.44% from 2025 to 2032.
  44. [44]
    https://www.izotope.com/en/learn/digital-audio-basics-sample-rate-and-bit-depth
  45. [45]
    High-Resolution Audio (Audiophile Audio) Market Size, Forecast
    Rating 4.5 (48) High-Resolution Audio (Audiophile Audio) Market size was valued at $32.8 Bn in 2023 and is projected to reach $78 Bn in 2030, growing at a CAGR of 12.3%
  46. [46]
    FLAC - Format - Xiph.org
    The FLAC format is described in great detail in RFC 9639. That document also defines the mapping of FLAC in the Ogg and Matroska (mkv) containers.
  47. [47]
    About lossless audio in Apple Music - Apple Support
    In addition to AAC, most of the Apple Music catalog is now also encoded using ALAC in resolutions ranging from 16-bit/44.1 kHz (CD Quality) up to 24-bit/192 kHz ...
  48. [48]
    https://www.digitaltrends.com/home-theater/what-is-mqa/
  49. [49]
    Monkey's Audio - a fast and powerful lossless audio compressor
    Monkey's Audio is a fast, lossless compressor that makes perfect copies of music, unlike mp3, and saves space while maintaining quality.Download · Help · Theory · License
  50. [50]
    What is MQA? The controversial digital audio format fully explained
    Sep 19, 2023 · MQA critics argue that while this authentication angle is a legitimate benefit, too often MQA files are not created by the artist or even an ...
  51. [51]
    Digital File Sizes and Storage Requirements - Galen Carol Audio
    Here's a guide to different file types by bitrate and bit depth/sample rate and their associated storage requirements ; 24-bit/96kHz. 33MB. 630 ; 24-bit/192kHz.
  52. [52]
    AES Standard » AES5-2018 (r2023) - Audio Engineering Society
    A sampling frequency of 48 kHz is recommended for the origination, processing, and interchange of audio programs employing pulse-code modulation.
  53. [53]
    https://roon.app/en/sound-quality
  54. [54]
    Exclusive Core Player - Audirvāna 2025 - Digital Audio
    Digital audio playback is at the heart of Audirvāna's exclusive core player technology, prioritizing the music on your computer with the shortest software ...
  55. [55]
    High-Quality Audio with Roon - DSP, Room Correction & Bit-Perfect ...
    Jun 12, 2023 · Our MUSE audio engine supports bit-perfect playback of lossless and lossy file formats, including high-resolution audio content like PCM and DSD ...Missing: output | Show results with:output
  56. [56]
    foobar2000: Frequently Asked Questions
    **Summary of WASAPI and ASIO for High-Res Playback in Foobar2000:**
  57. [57]
    Converting sample types - Adobe Help Center
    Dec 16, 2021 · Although you can work with sample rates ranging from 6000 to 192,000 Hz in Adobe Audition, your sound card may not be capable of playing all ...Missing: 192 | Show results with:192<|separator|>
  58. [58]
    REAPER | Audio Production Without Limits
    ### Summary: Reaper's Support for High-Resolution Audio Workflows (24-bit/192 kHz)
  59. [59]
    How to get perfect sound from your DAC: Windows edition
    If you're playing a CD, its native 44.1kHz sampling is being converted by Windows to 48kHz. Likewise, if you're playing some 192kHz high resolution audio.
  60. [60]
    Neutron Music Player | Audiophile music playback with advanced DSP
    Features: Hi-Res Audio support (Android 4.4+, >= 24-bit, up to 1.536 MHz), Network music sources, DSP effects, Hi-Res Audio for Android based DAPs.Missing: certification | Show results with:certification
  61. [61]
    How to set sample rate in a VST3 plugin - Steinberg Forums
    May 4, 2023 · VST3 only supports the same sample rate for input and output. It's not possible to set the sample rate from the plug-in side. bitblit May 4 ...Is there a way to tell supported sample rates for VST plugins?Does project sample rate affect "lossless Audio" from VST Connect ...More results from forums.steinberg.netMissing: specification high
  62. [62]
    Audio Unit Development Fundamentals
    Jul 15, 2014 · Explains how to use Core Audio frameworks and the Core Audio SDK to create audio units.Missing: high- | Show results with:high-
  63. [63]
    Sound Quality - TIDAL
    HiRes FLAC on TIDAL can deliver superior sound in files as large as 24-bit, 192 kHz. FLAC is a two-channel, stereo format meaning music is mixed with a left and ...
  64. [64]
    Understanding music in high sound quality (streaming or ... - Qobuz
    For example, Hi-Res sound uses 24-Bit resolution with a sampling frequency ranging between 44.1 and 192 kHz. 24-Bit resolution promises a dynamic range of 144dB ...
  65. [65]
    Apple Music announces Spatial Audio and Lossless Audio
    May 17, 2021 · Apple Music is bringing industry-leading sound quality to subscribers with the addition of Spatial Audio with support for Dolby Atmos.
  66. [66]
    What is High Definition (HD) and Ultra High Definition ... - Amazon.com
    HD audio quality is more than double the quality of standard quality streaming services. Ultra HD audio quality is up to 10 times the quality of standard ...
  67. [67]
    What audio quality does Amazon Music Unlimited support?
    Nov 3, 2022 · Ultra HD tracks have a bit depth of 24 bits, with sample rates ranging from 44.1 kHz up to 192 kHz, and an average bitrate of 3730 kbps. Engine ...
  68. [68]
    The Best Music Streaming Services for High-Res Audio in 2025
    Tidal · Available at TIDAL Music ; Amazon Music Unlimited · Available at Amazon ; Apple Music · $10.99 Per Month at Apple Music ; Qobuz · Starts at $10.83 Per Month at ...
  69. [69]
    Unlimited Hi-Res streaming offers - From $10.83/month - Qobuz
    Studio quality streaming (Lossless, FLAC 24-Bit up to 192 kHz) · Over 100 million tracks · Original editorial content · Offline listening · Discounts on Hi-Res ...Discover high-quality sound · Qobuz Family · Qobuz Sublime · Qobuz DuoMissing: specs | Show results with:specs
  70. [70]
    Amazon Music Unlimited - Review 2024 - PCMag Middle East
    Rating 4.0 Sep 30, 2024 · All Amazon Music Unlimited subscribers enjoy songs in HD quality (up to 850Kbps, 16-bit at 44.1kHz) and more than 7 million songs in Ultra HD ...<|separator|>
  71. [71]
    7 Best Music Streaming Services for High-Quality Audio in 2025
    Jul 26, 2025 · Spatial Audio with Dolby Atmos delivers three-dimensional sound positioning. Apple Music Sing enables vocal track control and real-time lyric ...
  72. [72]
    24-bit/192 kHz = 9216 kbps so how many bit depth and sample rate ...
    Jan 2, 2023 · So it is called a 16/44.1 file. You can record or buy audio files with more bit depth such as 24 bit or 32 bit and with higher sampling rates ...Where Can I Find Songs in the Highest Quality (24-bit/192KHz)?Can someone explain to me the differences between "kbps" and "bit ...More results from www.reddit.com
  73. [73]
    How Much Speed Do I Need to Stream Music?
    May 26, 2023 · Any internet plan with speeds of 10Mbps or more can stream average-quality music. Some music streaming services like Apple Music and Tidal offer ...
  74. [74]
    Amazon Music Unlimited with Dolby Atmos
    Ultra HD enables lossless stereo audio streaming at high resolutions (24-bit at 44.1 kHz or higher). Both of these rely on existing stereo mixes as their source ...
  75. [75]
    HDtracks
    HDtracks is a high-resolution music platform for music lovers to download their favorite tracks in master studio quality. Join us today for the ultimate ...
  76. [76]
    Where can you buy hi-res music? Here are the top download sites
    Sep 6, 2022 · Where can you buy hi-res music? Here are the top download sites · HDtracks · Qobuz · 7digital · Native DSD.
  77. [77]
    7digital United States | High quality DRM-free MP3 music downloads
    7digital provides a catalogue of over 30 million high-quality music tracks and a wealth of uniquely curated recommendations. Browse, buy, preview and ...
  78. [78]
    7digital Expands High Quality 24-bit and 16-bit FLAC Format ...
    7digital releases 24-bit and 16-bit FLAC format music section 'Better-than-CD' quality downloads available across 32 territories, including UK, US, ...
  79. [79]
    Which audio format should I download? - Bandcamp Help Center
    You can also download in FLAC, ALAC (Apple Lossless), AAC, Ogg Vorbis, WAV and AIFF formats. These options are, ahem, for “audiophiles and nerds.” If you aspire ...
  80. [80]
    Sony Launches Super Audio CD
    Apr 6, 1999 · Sony Corporation today announced plans to begin selling Super Audio CD players and related products on the Japanese market on May 21, 1999.
  81. [81]
    Conventional high-quality Audio CDs - UHQCD
    We developed our conventional high-quality Audio CD discs through an effort to improve audio quality by simply upgrading the materials used in ordinary CD ...
  82. [82]
    Highest-quality audiophile recordings: 180-gram LPs | Gold CDs ...
    We make the highest-quality audiophile recordings: 180-gram LPs, 24K Gold CDs, and SACDs that redefine definitive to put you in the music.Catalog · Vinyl Records · New Records Are Coming Out! · What We Do
  83. [83]
    Sound Preservation at the Library of Congress | About This Program
    ... transferring its collection from their original formats to high-resolution digital audio broadcast WAV files (96 kHz/24 bit). These computer files can be ...
  84. [84]
    The Rise and Fall of the Compact Disc - High Resolution Audio
    Sep 7, 2025 · In 2023 sales of music on physical media in the US were 10.5% of the total a significant increase on 2020 when sales had fallen to 9%. In ...Cd Sales Continue To Fall In... · Cd Singles · The Future Of The Cd Is...
  85. [85]
    USBs for Music | Disc Makers
    Get custom printed music flash drives to distribute your tunes and connect with fans! Two popular styles: Cassette USBs & USB Music Cards.
  86. [86]
    https://www.aes.org/e-lib/browse.cfm?elib=14195
  87. [87]
    https://qmro.qmul.ac.uk/xmlui/bitstream/handle/123456789/13493/Reiss%20A%20Meta-Analysis%20of%20High%20Resolution%202016%20Published.pdf
  88. [88]
    https://www.qualcomm.com/content/dam/qcomm-martech/dm-assets/documents/the_state_of_sound_2021_report.pdf
  89. [89]
    https://www.apple.com/apple-music-lossless/