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AptX Adaptive vs. aptX HD vs. LDAC: Which Bluetooth codec is the best?

When it comes to Bluetooth codecs, most wireless earbuds and headphones will support AAC and/or aptX (in addition to the standard SBC codec that all devices support). These three codecs differ in how they compress the audio that travels from your phone to your headphones, but they all have one thing in common: They only support a bit depth of 16 bits. That’s enough resolution for most kinds of audio, and many experts believe it’s enough, period.

Not everyone is convinced that hi-res audio actually sounds better, but if you’ve got access to a source of lossless, 24-bit music, whether from your own personal files or from a streaming music service, you may want to consider buying a set of buds or headphones that can support a Bluetooth codec designed to deliver that extra level of detail. The three most common 24-bit compatible codecs are aptX HD, aptX Adaptive, and LDAC.

Qualcomm, which designs chips for mobile phones and other wireless devices, is the driving force behind the aptX family of codecs. Sony created LDAC, and you will find that the company uses it extensively on its own products.

But which of these codecs is the best? That depends on a lot of factors, so let’s start at the beginning.

Compatibility and availability

Xiaomi 12 Pro showing available codecs.
Simon Cohen / Digital Trends

The first thing you should know about these three codecs is that none are currently supported by Apple on its devices. If you own an iPhone or iPad, or even a Mac, you are most likely limited to the 16-bit AAC codec. On some older Macs running macOS versions earlier than Catalina, it’s possible — with some work — to get aptX support, but even then, you’re still limited to 16-bit audio.

AptX HD and LDAC were both added by Google to Android 8.0, letting any Android smartphone manufacturer take advantage of them. If your phone is on Android 8.0 or higher (and as long as your phone’s manufacturer hasn’t intentionally disabled one or both), you should be able to use them with a compatible set of earbuds or headphones.

AptX Adaptive is the newest of the three codecs, and while it also runs on Android devices, it’s not built into the Android operating system. Only Android phones that use Qualcomm’s audio chipsets can support aptX Adaptive. Still, if we’re talking about Android phones that have been released since about 2020, aptX Adaptive support is very good across all of the major brands and many smaller ones — with one very notable exception: No Google Pixel phones currently support aptX Adaptive.

Any wireless headphones or earbuds that support aptX Adaptive must also use Qualcomm’s chips. From a compatibility and availability point of view, this puts aptX Adaptive at a bit of a disadvantage.

AptX HD has limitations too, but in this case, it’s strictly on the headphones side of the equation. For reasons we’ll get into shortly, aptX HD is primarily used for wireless headphones, not wireless earbuds. There are some exceptions — like the Bowers & Wilkins PI7 — but they’re very rare. If you’re shopping for wireless earbuds, they will most likely offer aptX or aptX Adaptive, but not aptX HD.

LDAC has no real constraints on either side of the Bluetooth equation. It works on headphones and earbuds, and even though the codec is owned and licensed by Sony, a manufacturer doesn’t need to use Sony’s chips to add LDAC support to their products — it can be implemented using software on a variety of processing platforms. This makes LDAC the easy winner for compatibility.

Availability is a slightly different story. Not many manufacturers have chosen to adopt LDAC. Other than Sony itself, the list includes 1More, Anker Soundcore, Soundpeats, Shure, Audio-Technica, Technics, Edifier, Ausounds, Ankbit, and Philips. Meanwhile, aptX HD has been used by more than 30 headphone manufacturers, and aptX Adaptive has been used by even more companies when you count both headphones and earbuds.

In theory, with LDAC’s ability to run on headphones and earbuds, and its software-based implementation, it should be the most widely used of the 24-bit codecs. However, that isn’t how it has played out — at least so far.

Winner: aptX Adaptive

Sound quality part 1: resolution and frequency

LDAC Vs. SBC comparison from Sony.
Sony

Sound quality is a highly subjective topic and can be influenced by a variety of factors. For instance, if you’re using a set of budget headphones to listen to compressed music, your choice of Bluetooth codec probably won’t make any difference to what you’re hearing. Because of this, we’ll avoid making any judgment calls on which codec sounds best. Instead, let’s take a look at each codec’s potential based on its technology and specifications.

When a codec is used to transmit audio wirelessly, it encodes that audio at a specific resolution (bit depth) and a specific sample frequency (kHz). Generally speaking, the higher these numbers, the more information will be preserved, and the better your audio has the potential to sound.

AptX HD operates at 24 bits and up to 48kHz. By any standards, that should be more than enough to capture and transmit very high-quality audio. However, in order to technically be considered “hi-res,” a codec needs to support sample frequencies above 48kHz. LDAC and aptX Adaptive both meet that criteria, with a top quality of 24-bit/96kHz. Whether you’ll be able to hear that difference or not is highly debatable, but if you’re listening to 24-bit/96kHz or better audio and want to preserve as much of that signal as possible, LDAC and aptX Adaptive are the way to go.

Winner: Two-way tie between LDAC and aptX Adaptive

Sound quality part 2: bit rate and scalability

The nerds out there are probably yelling at me right now because while resolution and sample frequency might be the be-all and end-all for sound quality when dealing with hi-res audio files, the moment Bluetooth gets involved, you also need to take into account how a codec handles itself under highly variable wireless conditions.

We’re talking about bit rate, or the amount of data a codec uses to send information across a Bluetooth connection. The higher the bit rate, the more information can be sent, and thus the better the sound quality.

Some codecs have fixed bit rates, which means that they can’t react to changes in the quality of a wireless link. AptX HD is a fixed bit rate codec, and it requires a constant speed of 576Kbps when using a 48kHz sampling frequency. As long as your connection can handle this speed, aptX HD should be able to deliver its full quality. But if the quality of your connection drops below that speed, which can happen when you’re too far from your phone or there’s a lot of wireless interference, the audio will start to break up. It’s an all-or-nothing proposition.

LDAC and aptX Adaptive are scalable codecs — they can adjust the amount of bandwidth they use in response to your Bluetooth connection. The difference between them is that LDAC steps between three specific speeds: 330Kbps, 660Kbps, and 990Kbps, with no in-between steps, while aptX Adaptive can dynamically adjust its speed from as low as 110Kbps and as high as 620Kbps in 10Kbps increments.

It’s rare that a Bluetooth connection can be maintained at LDAC’s top speed of 990Kbps — this really requires ideal conditions. Unless you force your phone to only use the 990Kbps speed (which is possible using the optional developer settings), LDAC will typically run at 660, and even that may be difficult to maintain.

AptX Adaptive’s ability to smoothly scale instead of stepping in such large increments, and its lower overall speed requirements means it will be able to connect at its top quality more of the time while presenting a far less noticeable transition when it needs to ramp its speed downward.

On paper, LDAC’s 990Kbps bitrate is clearly the best of the three, with almost double the amount of data transmitted per second than aptX HD and almost 50% more than aptX Adaptive. However, there’s not much point in being able to achieve 990Kbps if conditions almost never allow it to happen. And as we’ll see in a moment, what you do with that bit rate is just as important.

Winner: aptX Adaptive

Sound quality part 3: efficiency

As the newest of the three codecs, you’d expect aptX Adaptive to be the most efficient (the ability to maintain the greatest amount of detail with the least amount of transmitted data), and it is. In some ways, it’s not even a fair comparison. Not only is aptX Adaptive newer in terms of its code, it only runs on Qualcomm’s chips, effectively giving it a home-field advantage.

Qualcomm claims that aptX Adaptive can deliver the same audio quality as aptX HD (576Kbps) at just 420Kbps. And though Qualcomm makes no direct claims about LDAC, we know that aptX Adaptive can deliver the same 24-bit/96kHz mode as LDAC’s 990Kbps at just 660Kbps.

We haven’t been able to find a scientific set of measurements that clearly shows how LDAC and aptX Adaptive perform at their respective top bit rates, but it’s worth repeating: If a codec can’t deliver its top level of quality without a very hard-to-reach bit rate, does it really matter?

Winner: aptX Adaptive

Latency

An intense-looking gamer with a gaming headset on.
Shutterstock by Gorodenkoff

Latency is the time it takes for you to hear a sound after it has been created by your device. For regular music listening, latency doesn’t matter much, but if you’re gaming or watching any kind of video with dialogue, you want that time to be as short as possible. The general consensus within the gaming community is that anything lower than 32ms is fast enough to be comparable to using a wired headset.

Several factors can affect Bluetooth audio latency, but codecs are an important ingredient. AptX HD has a reported latency of anywhere between 200ms and 300ms. LDAC can exhibit similarly long lag times.

AptX Adaptive, on the other hand, can adjust its performance based on the kind of audio you’re streaming. If it detects that you’re gaming, making a phone call, or doing anything else that might require low latency over high resolution, it can operate as low as 80ms.

That’s enough to earn it a win in the latency category, but it might get even better. Qualcomm says that if you’re using a phone and wireless headphones that have both been certified under its Snapdragon Sound program, latency as low as 40ms — the same performance as its aptX Low Latency codec — could be possible.

Winner: aptX Adaptive

Power consumption

App screenshot showing remaining battery life.
Image used with permission by copyright holder

One thing we’ll probably never get enough of when it comes to wireless headphones and earbuds is battery life. No one likes to recharge, so the less frequently we need to do it, the better.

For LDAC, this poses a challenge. Running LDAC on a set of earbuds or headphones can mean a measurable reduction in playtime. On Anker Soundcore’s recently released Liberty 4 earbuds, engaging the LDAC codec drops their playtime from nine hours per charge to just six hours.

The aptX family of codecs has always been more efficient than its rivals, and that goes for both aptX HD and aptX Adaptive. Low power consumption isn’t a key feature of Adaptive, but Qualcomm says it uses less power to deliver the same performance as aptX HD. These efficiencies will likely get better over time thanks to improvements in Qualcomm’s chips.

Winner: aptX Adaptive

Conclusion

In some ways, this wasn’t a fair comparison. As the newest of the three codecs, AptX Adaptive has several advantages that LDAC and aptX HD simply can’t match. It works on earbuds and headphones alike, it doesn’t require a near-perfect wireless connection to deliver 24-bit/96kHz audio, and it can respond to ever-changing conditions quickly and seamlessly so you can always hear your tunes. It doesn’t require a lot of extra power, and while it may not be standard equipment within the Android operating system, you can find tons of smartphones and wireless audio devices that support it.

Our overall winner: aptX Adaptive

Simon Cohen
Simon Cohen covers a variety of consumer technologies, but has a special interest in audio and video products, like spatial…
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