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Cortex-A76
https://www.cnx-software.com/2021/12/16/rockchip-rk3588-datasheet-sbc-coming-soon/
peut être bientôt dans les futurs autoradio, ça devrait avoiner.
CNX-Software remonte quelques tests qui montrent que le RK3588 est 2.7 fois plus performant en single-core sous Geekbench 4 que le précédent RK3399. Cette évolution monte à 3.4 fois en multi-core.
La partie graphique est, quant à elle, 6 fois plus rapide…
Antutu 9 score is about 540,000 points.
CPU – 4x Cortex-A76 @ up to 2.4/2.6 GHz and 4x Cortex-A55 cores @ 1.8 GHz in dynamIQ configuration
GPU
Arm Mali-G610 MP4 “Odin” GPU with support for OpenGLES 1.1, 2.0, and 3.2, OpenCL up to 2.2 and Vulkan1.2
2D graphics engine up to 8192×8192 source, 4096×4096 destination
Video decoding
8Kp60 H.265, VP9, AVS2, 8Kp30 H.264 AVC/MVC
4Kp60 AV1
1080p60 MPEG-2/-1, VC-1, VP8
Real-time 8Kp30 encoding with H.265/H.264; multi-channel encoding supported at lower resolutions
Memory I/F – LPDDR4/LPDDR4x/LPDDR5 up to 32GB
Storage – eMMC 5.1, SD/MMC, SATA 3.0 (multiplexed with PCIe 2.0), FSPI (Flexible SPI)
Video Output
Dual HDMI 2.1 / eDP 1.3 up to 8Kp60
Dual DisplayPort 1.4a up to 8Kp30 (multiplexed with USB 3.0)
Dual MIPI DSI output up to 4Kp60
Bt.1120 video output up to 1080p60
Optional dual LVDS up to 1080p60 via RK628 chip.
Up to four independent displays (up to 1x 8Kp60, 2x 4Kp60, 1x 1080p60)
Video Input/Camera
48MP (2x 24MP) ISP with HDR and 3D NR support; multi-camera input
2x MIPI DC (4-lane DPHY v2.0 or 3-lane CPHY V1.1),4x 2-lane MIPI CSI, DVP camera interface
HDMI Rx 2.0 interface up to 4Kp60 with HDCP 2.3 support
Audio
2x 8-channel I2S, 2x 2-channel I2S, 2x SPDIF, 2x 8-channel PDM (for mic arrays), 2-channel digital audio codec (16-bit DAC)
VAD engine
Networking – Dual Gigabit Ethernet
USB – 2x USB 3.1 Gen 1 up to 5 Gbps (multiplexed with DisplayPort), 1x USB 3.1 Gen 1 (multiplexed with Combo “PIPE PHY2”), 2x USB 2.0 OTG
PCIe – PCIe 3.0 up to 8 Gbps (1x 4-lane, or 2x 2-lane, or 4x 1-lane, or 1x 2-lane + 2x 1-lane
3x Combo PIPE PHY interfaces
Combo PIPE PHY0/1 – SATA III or PCIe2.1 up to 5 Gbps
Combo PIPE PHY2 – SATA III, PCIe 2.1, or USB 3.0
Low-speed I/O – 5x SPI, 9x I2C, 10x UART, GPIOs, 12-bit ADC (SARADC)
Package – FCBGA1088L; 21.45 x 21.45mm
Manufacturing process – 8nm LP
peut être bientôt dans les futurs autoradio, ça devrait avoiner.
CNX-Software remonte quelques tests qui montrent que le RK3588 est 2.7 fois plus performant en single-core sous Geekbench 4 que le précédent RK3399. Cette évolution monte à 3.4 fois en multi-core.
La partie graphique est, quant à elle, 6 fois plus rapide…
Antutu 9 score is about 540,000 points.
CPU – 4x Cortex-A76 @ up to 2.4/2.6 GHz and 4x Cortex-A55 cores @ 1.8 GHz in dynamIQ configuration
GPU
Arm Mali-G610 MP4 “Odin” GPU with support for OpenGLES 1.1, 2.0, and 3.2, OpenCL up to 2.2 and Vulkan1.2
2D graphics engine up to 8192×8192 source, 4096×4096 destination
Video decoding
8Kp60 H.265, VP9, AVS2, 8Kp30 H.264 AVC/MVC
4Kp60 AV1
1080p60 MPEG-2/-1, VC-1, VP8
Real-time 8Kp30 encoding with H.265/H.264; multi-channel encoding supported at lower resolutions
Memory I/F – LPDDR4/LPDDR4x/LPDDR5 up to 32GB
Storage – eMMC 5.1, SD/MMC, SATA 3.0 (multiplexed with PCIe 2.0), FSPI (Flexible SPI)
Video Output
Dual HDMI 2.1 / eDP 1.3 up to 8Kp60
Dual DisplayPort 1.4a up to 8Kp30 (multiplexed with USB 3.0)
Dual MIPI DSI output up to 4Kp60
Bt.1120 video output up to 1080p60
Optional dual LVDS up to 1080p60 via RK628 chip.
Up to four independent displays (up to 1x 8Kp60, 2x 4Kp60, 1x 1080p60)
Video Input/Camera
48MP (2x 24MP) ISP with HDR and 3D NR support; multi-camera input
2x MIPI DC (4-lane DPHY v2.0 or 3-lane CPHY V1.1),4x 2-lane MIPI CSI, DVP camera interface
HDMI Rx 2.0 interface up to 4Kp60 with HDCP 2.3 support
Audio
2x 8-channel I2S, 2x 2-channel I2S, 2x SPDIF, 2x 8-channel PDM (for mic arrays), 2-channel digital audio codec (16-bit DAC)
VAD engine
Networking – Dual Gigabit Ethernet
USB – 2x USB 3.1 Gen 1 up to 5 Gbps (multiplexed with DisplayPort), 1x USB 3.1 Gen 1 (multiplexed with Combo “PIPE PHY2”), 2x USB 2.0 OTG
PCIe – PCIe 3.0 up to 8 Gbps (1x 4-lane, or 2x 2-lane, or 4x 1-lane, or 1x 2-lane + 2x 1-lane
3x Combo PIPE PHY interfaces
Combo PIPE PHY0/1 – SATA III or PCIe2.1 up to 5 Gbps
Combo PIPE PHY2 – SATA III, PCIe 2.1, or USB 3.0
Low-speed I/O – 5x SPI, 9x I2C, 10x UART, GPIOs, 12-bit ADC (SARADC)
Package – FCBGA1088L; 21.45 x 21.45mm
Manufacturing process – 8nm LP
Rockchip RK3588 featuring Cortex-A76 and Cortex-A55 cores, 8K video decoding support, 4K user interface support,
an NPU 2.0 (Neural Processing Unit)
RK3588
The processor should have eight cores in a 4+4 dynamIQ configuration
the new 8nm process is expected to increase performance by 20 to 30 percent, while the power consumption will be reduced by 40 percent.
Mass production is expected for Q1 2020.
Rockchip Video Encoder DecoderThe company also showed a slide with their video encoder/decoder IP, and Gen3 should be in RK3588 since that’s the only one with an 8K 60 fps decoder using either AVS3 or H.266 (VVC). I’m quite confused with the Gen1 decoder since it shows AV1 implementation too, and as such should be new as well.
An 8K 60 fps video encoder is also in the works.
H266 (je savais même pas que c'était déjà prévu)
" le codec HEVC H.266 est en préparation et sa normalisation est attendue pour octobre 2020."
an NPU 2.0 (Neural Processing Unit)
RK3588
The processor should have eight cores in a 4+4 dynamIQ configuration
the new 8nm process is expected to increase performance by 20 to 30 percent, while the power consumption will be reduced by 40 percent.
Mass production is expected for Q1 2020.
Rockchip Video Encoder DecoderThe company also showed a slide with their video encoder/decoder IP, and Gen3 should be in RK3588 since that’s the only one with an 8K 60 fps decoder using either AVS3 or H.266 (VVC). I’m quite confused with the Gen1 decoder since it shows AV1 implementation too, and as such should be new as well.
An 8K 60 fps video encoder is also in the works.
H266 (je savais même pas que c'était déjà prévu)
" le codec HEVC H.266 est en préparation et sa normalisation est attendue pour octobre 2020."