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AV1 Capped CRF Encoding with Quadra VPU

Jan Ozer

Jan Ozer

is Senior Director of Video Marketing at NETINT.

Jan is also a contributing editor to Streaming Media Magazine , writing about codecs and encoding tools. He has written multiple authoritative books on video encoding, including ‘Video Encoding by the Numbers: Eliminate the Guesswork from your Streaming Video’ and ‘ Learn to Produce Video with FFmpeg: In Thirty Minutes or Less’ and has produced multiple training courses relating to streaming media production.

We’ve previously reported results for capped CRF encoding for H.264 and HEVC using NETINT Quadra video processing units (VPU). This post will detail AV1 performance, including both 1080p and 4K data.

For those with limited time, here’s what you need to know: Capped CRF delivers higher quality video during hard-to-encode regions than CBR, similar quality during all other scenes, and improved quality of experience at the same cost or lower than CBR. NETINT VPUs are the first hardware video encoders to adopt Capped CRF across the three most popular codecs in use today, AV1, HEVC, and H.264.

You can read a quick description of capped CRF here and get a deep dive with H.264 and HEVC performance results here


Briefly, capped CRF is a smart bitrate control technique that combines the benefits of CRF encoding with a bitrate cap. Unlike variable bitrate encoding (VBR) and constant bitrate encoding (CBR), which target specific bitrates, capped CRF targets a specific quality level, which is controlled by the CRF value. You also set a bitrate cap, which is applied if the encoder can’t meet the quality level below the bitrate cap.

On easy-to-encode videos, the CRF value sets the quality level, which it can usually achieve below the bitrate cap. In these cases, capped CRF typically delivers bitrate savings over CBR-encoded footage while delivering similar quality. For harder-to-encode footage, the bitrate cap usually controls, and capped CRF delivers close to the same quality and bitrate as CBR.

The value proposition is clear: lower bitrates and good quality during easy scenes, and similar to CBR in bitrate and quality for harder scenes. I’m not addressing VBR because NETINT’s focus is live streaming, where CBR usage dominates. If you’re analyzing capped CRF for VOD, you would compare against 2-pass VBR as well as potentially CBR.

One last detail. CRF values have an inverse relationship to quality and bitrate; the higher the CRF value, the lower the quality and bitrate. In general, video engineers select a CRF value that delivers their target quality level. For premium content, you might target an average VMAF score of 95. For user-generated content or training videos, you might target 93 or even lower. As you’ll see, the lower the quality score, the greater the bandwidth savings.


We show 1080p results in Table 1, which is divided between easy-to-encode and hard-to-encode content. We encoded the CBR clips to 4.5 Mbps and applied the same cap for capped CRF encoding.

Jan Ozer-AV1 Capped CRF-1
Table 1. 1080p results using Quadra VPU and capped CRF encoding.

You see that in CBR mode, Quadra VPUs do not reach the target rate as accurately as when using capped CRF mode. This won’t degrade viewer quality of experience since the VMAF scores exceed 95, so this missing on the low side saves excess bandwidth with no visual quality detriment.

In this comparison, bitrate savings is minimized, particularly at CRF 19 and 21, as the capped CRF clips in the hard-to-encode content have a higher bitrate than the CBR counterparts (4,419 and 4,092 to 3,889). Not surprisingly, CRF 19 and 21 deliver little bandwidth savings and a slighly higher quality than CBR.

At CRF 23, things get interesting, with an overall bandwidth savings of 16.1% with a negligible quality delta from CBR. With a VMAF score of around 95, CRF 23 might be the target for engineers delivering premium content. Engineers targeting slightly lower quality can choose CRF 27 and achieve a bitrate savings of 43%, and an efficient 2.4 Mbps bit rate for hard-to-encode footage. At CRF 27, Quadra VPUs encoded the hard-to-encode Football clip at 3,999 kbps with an impressive VMAF score of 93.39.

Note that as with H.264 and HEVC, AV1 capped CRF does reduce throughput. Specifically, a single Quadra VPU installed in a 32-core workstation outputs 23 simultaneous CBR streams using CBR encoding. This dropped to eighteen for capped CRF, a reduction of 22%.


Many engineers encoding with AV1 are delivering UHD content, so we ran similar tests with the Quadra and 4K30 8-bit content with a CBR target and bitrate cap of 16 Mbps. Using four clips, including a 4K version of the high-motion Football clip to much less dynamic content like Netflix’s Meridian clip and Blender Foundation’s Sintel.

Table 2. 4K results for the Quadra VPU and capped CRF encoding.

In CBR mode, the Quadra VPU hit the bitrate target much more accurately at 4K than 1080p, so even at CRF 19, the VPU delivered a 13% bitrate savings with a VMAF score of 96.23. Again, CRF 23 delivered a VMAF score of very close to 95, with 45% savings over CBR. Impressively, at CRF 23, Quadra delivered an overall VMAF score of 94.87 for these 4K clips at 7.78 Mbps, and that’s with the Football clip weighing in at 14.3 Mbps.

Of course, these savings directly relate to the cap and CBR target. It’s certainly fair to argue that 16 Mbps is excessive for 4K AV1-encoded content, though Apple recommends 16.8 for 8-bit 4K content with HEVC here.

The point is, when you encode with CBR, you’re limiting quality to control bandwidth costs. With capped CRF, you can set the cap higher than your CBR target, knowing that all content contains easy-to-encode regions that will balance out the impact of the higher cap and deliver similar or lower bandwidth costs. With these comparative settings, capped CRF delivers higher quality video during hard-to-encode regions than CBR, similar quality during all other scenes, and improved quality of experience at the same cost or lower than CBR.

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