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Nous préparons un guide éducatif complet pour le Video Bitrate Calculator. Revenez bientôt pour des explications étape par étape, des formules, des exemples concrets et des conseils d'experts.
The Video Bitrate Calculator determines the appropriate video bitrate for a given resolution, frame rate, codec, and quality level, and calculates the resulting file size for a specific duration. Video bitrate — measured in megabits per second (Mbps) or kilobits per second (Kbps) — defines how much digital data is used per second of video. Higher bitrate preserves more detail and reduces compression artifacts, but produces larger files and requires faster storage for recording. The relationship between resolution, frame rate, codec efficiency, and bitrate is complex: modern codecs like H.265 (HEVC), AV1, and Apple ProRes achieve the same visual quality as older codecs (H.264, ProRes 422) at roughly half the bitrate. Standard industry recommendations for distribution bitrates include YouTube's guidelines (35–68 Mbps for 4K/60fps H.264; 15–30 Mbps for H.265), Netflix's per-title encoding specifications, and Vimeo's upload requirements. Camera manufacturers publish recording bitrate specifications — for example, the Sony FX3 records at up to 600 Mbps in XAVC-I 4K, while the DJI Mavic 3 Pro records up to 200 Mbps H.265. Understanding bitrate helps videographers choose appropriate recording formats for their intended delivery platform, manage on-set storage capacity, select the right drives for reliable recording (minimum 400 MB/s for 4K RAW), and estimate post-production storage needs. The calculator supports CBR (Constant Bitrate), VBR (Variable Bitrate), and CRF (Constant Rate Factor) encoding approaches, which affect file size predictability and overall quality.
File Size (GB) = Bitrate (Mbps) × Duration (seconds) / 8 / 1024 File Size (MB) = Bitrate (Mbps) × Duration (seconds) / 8 Required Bitrate (Mbps) = File Size (MB) × 8 / Duration (seconds) Recommended Bitrate = Resolution Factor × Frame Rate Factor × Codec Factor × Quality Factor
- 1Step 1: Select your output resolution (1080p, 4K, 6K, 8K) and frame rate (24, 25, 30, 48, 60 fps).
- 2Step 2: Choose your codec: H.264, H.265 (HEVC), AV1, ProRes 422, ProRes 4444, Blackmagic RAW, etc.
- 3Step 3: Determine quality level: streaming/web delivery, broadcast master, archival.
- 4Step 4: Use the recommended bitrate from platform guidelines or the formula, or reference the codec manufacturer's recommendations.
- 5Step 5: Calculate file size: File Size (MB) = Bitrate (Mbps) × Duration (s) / 8. Convert to GB for longer content.
- 6Step 6: Verify the required write speed for the bitrate against your storage medium's rated speed.
YouTube recommends 53–68 Mbps for 4K/60fps H.264. At 68 Mbps: 68 × 600s / 8 = 5,100 MB = 4.98 GB ≈ 5 GB for a 10-minute video.
Netflix's per-title encoding delivers 1080p H.265 content at 4–6 Mbps for most content types. HEVC efficiency vs. H.264 allows ~50% bitrate reduction at equivalent quality.
The Sony FX3's highest 4K/60 recording mode uses 600 Mbps. 600 × 1800s / 8 = 135,000 MB = 131.8 GB. Requires CFexpress Type A cards with 400 MB/s+ write speed.
200 Mbps × 1200s / 8 = 30,000 MB = 29.3 GB. A 128 GB microSD can hold approximately 84 minutes of 200 Mbps 4K H.265 footage.
Videographers estimating on-set storage needs for a full production day., representing an important application area for the Video Bitrate Calc in professional and analytical contexts where accurate video bitrate calculations directly support informed decision-making, strategic planning, and performance optimization
Post-production supervisors planning NAS server capacity for editorial projects., representing an important application area for the Video Bitrate Calc in professional and analytical contexts where accurate video bitrate calculations directly support informed decision-making, strategic planning, and performance optimization
Content creators optimizing upload settings for YouTube, Vimeo, and streaming platforms., representing an important application area for the Video Bitrate Calc in professional and analytical contexts where accurate video bitrate calculations directly support informed decision-making, strategic planning, and performance optimization
Broadcast engineers specifying encoding requirements for live streaming events., representing an important application area for the Video Bitrate Calc in professional and analytical contexts where accurate video bitrate calculations directly support informed decision-making, strategic planning, and performance optimization
RAW video recording
{'title': 'RAW video recording', 'body': 'Cinema cameras (ARRI ALEXA, RED, Blackmagic URSA) record RAW sensor data at extremely high bitrates (1,000–12,000 Mbps). RAW is not compressed in the traditional sense but captures all sensor data for maximum post-production flexibility. File sizes are enormous: 1 hour of 6K Blackmagic RAW at 3:1 compression = approximately 180 GB.'}
Hardware-limited encoding
Many cameras offer lower bitrates in 4K than they could theoretically achieve because of thermal and processing constraints. External recorders (Atomos Shogun, Blackmagic Video Assist) connect via HDMI or SDI to record higher-quality ProRes or BRAW formats than the camera's internal recording supports."}
When using the Video Bitrate Calc for comparative video bitrate analysis across
When using the Video Bitrate Calc for comparative video bitrate analysis across scenarios, consistent input measurement methodology is essential. Variations in how video bitrate inputs are measured, estimated, or rounded introduce systematic biases compounding through the calculation. For meaningful video bitrate comparisons, establish standardized measurement protocols, document assumptions, and consider whether result differences reflect genuine variations or measurement artifacts. Cross-validation against independent data sources strengthens confidence in comparative findings.
| Platform / Use | Resolution | Frame Rate | Codec | Recommended Bitrate |
|---|---|---|---|---|
| YouTube | 1080p | 30fps | H.264 | 8 Mbps |
| YouTube | 4K | 30fps | H.264 | 35–45 Mbps |
| YouTube | 4K | 60fps | H.264 | 53–68 Mbps |
| Vimeo | 1080p | 24fps | H.264 | 5 Mbps |
| Netflix (streaming) | 4K HDR | 24fps | H.265 | 15–20 Mbps |
| Broadcast (HD) | 1080i | 29.97fps | H.264 / MPEG-2 | 50 Mbps |
| Archival (Camera) | 4K | 60fps | ProRes 422 HQ | 220 Mbps |
| Cinema (DCI 4K) | 4096×2160 | 24fps | JPEG2000 | 250 Mbps |
What is the difference between CBR, VBR, and CRF encoding?
CBR (Constant Bitrate) maintains a fixed bitrate throughout the video, ensuring predictable file sizes and reliable streaming bandwidth requirements. VBR (Variable Bitrate) allocates more bits to complex scenes and fewer to simple ones, achieving better overall quality at the same average bitrate as CBR. CRF (Constant Rate Factor) is a quality-based encoding mode in FFmpeg/H.264/H.265 that targets a specific quality level regardless of bitrate — the encoder uses as many bits as needed. For archival and editing, use the highest bitrate available. For delivery, use VBR or CRF targeting the platform's recommended quality level.
How does frame rate affect required bitrate?
Higher frame rates require proportionally higher bitrates to maintain the same per-frame quality. Going from 24 fps to 60 fps (2.5× increase) ideally requires 2.5× the bitrate, though modern codecs use inter-frame prediction to encode motion efficiently, somewhat reducing this proportionality. A 24 fps, 4K H.264 video might need 35 Mbps; the same content at 60 fps would need approximately 50–68 Mbps for equivalent quality.
What bitrate should I use for ProRes editing?
Apple ProRes is a professional intermediate codec for editing workflows: ProRes 422 Proxy (~45 Mbps at 1080p24) for offline editing proxies; ProRes 422 LT (~102 Mbps) for standard editing; ProRes 422 (~147 Mbps) for professional HD editing; ProRes 422 HQ (~220 Mbps) for high-quality HD; ProRes 4444 (~330 Mbps) for visual effects with alpha channel; ProRes 4444 XQ (~500 Mbps) for HDR workflows. These are approximate rates at 1080p — 4K ProRes files are 4× larger.
What storage write speed is required for various bitrates?
Convert Mbps to MB/s (divide by 8) to find the required write speed. At 100 Mbps, you need ≥12.5 MB/s write speed — easily handled by UHS-I SD cards. At 600 Mbps (74 MB/s), you need CFexpress Type A or B cards. At 3,500 Mbps ProRes RAW 8K (437 MB/s), you need an NVMe SSD recorder. Always ensure your storage is rated at least 20% above the target bitrate for reliable recording.
Why does YouTube re-encode my video after upload?
YouTube transcodes all uploaded videos into multiple quality streams (360p, 720p, 1080p, 4K) for adaptive streaming. Even if you upload a high-quality 4K master, YouTube's re-encoding compresses it significantly. To minimize quality loss after YouTube's compression, upload the highest reasonable bitrate (use YouTube's recommended settings) and always export in H.264 or H.265 at their exact specified bitrates.
What is the benefit of 10-bit vs. 8-bit video recording?
10-bit recording captures 1024 tonal values per channel vs. 256 in 8-bit, giving 64× more color precision. This dramatically reduces banding in color grades and allows more aggressive color correction without visible posterization. 10-bit recording requires approximately 25% more storage than equivalent 8-bit content. For any serious color grading work — especially in LOG profiles or HDR workflows — 10-bit recording is strongly recommended.
How do I calculate how much footage fits on a memory card?
Card capacity (shots or minutes) = Card Size (GB) × 8000 (Mb per GB) / Bitrate (Mbps) / 60 (seconds per minute). For a 256 GB card recording at 200 Mbps: 256 × 8000 / 200 / 60 = 170 minutes. Always leave 10% of card capacity unused for performance and safety.
Conseil Pro
For YouTube delivery, export in H.264 at the recommended bitrate rather than H.265 even though H.265 is more efficient. YouTube's processing pipeline handles H.264 faster and with fewer artifacts in the final transcoded output as of 2024.
Le saviez-vous?
Netflix's per-title encoding algorithm, introduced in 2015, analyzes each scene's complexity and encodes different segments at different bitrates within the same video stream. A simple cartoon can stream at 235 Kbps at 1080p while a complex action film requires 5+ Mbps — this adaptive approach reduced Netflix's bandwidth consumption by approximately 20% globally.