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ROCKPro64 - Übersicht

Angeheftet Verschoben Hardware

8 Beiträge 1 Kommentatoren 5.7k Aufrufe

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FrankM
schrieb am zuletzt editiert von FrankM

#1
Das nächste Spielzeug (bestellt)

Bildquelle: https://www.pine64.org/?product=rockpro64-4gb-single-board-computer
- CPU: Rockchip RK3399 Hexa-Core (dual ARM Cortex A72 and quad ARM Cortex A53) 64-Bit Processor
- GPU: MALI T-860 Quad-Core GPU
- RAM: 4GB LPDDR4 system memory and 128Mb SPI boot Flash
- eMMC: yes, up to 128GB
- microSD: yes
- PCIe x4
- 1x USB 3.0 type C Host with DP 1.2
- 1x USB 3.0 type A Host
- 2x USB 2.0 Host
- Gigabit Ethernet
- PI-2 GPIO Bus
- MiPi DSI interface
- eDP interface
- touch Panel interface
- stereo MiPi CSI interface
- and many other peripheral device interface such as UART, SPI, I2C.
Webseite: https://www.pine64.org
Forum: https://forum.pine64.org
Wiki: http://wiki.pine64.org/index.php/ROCKPro64_Main_Page
Support: https://www.pine64.org/?page_id=702

Schaltdiagramm V2.0: http://files.pine64.org/doc/rockpro64/rockpro64_v20-SCH.pdf
Schaltdiagramm V2.1: http://files.pine64.org/doc/rockpro64/rockpro64_v21-SCH.pdf
Platinendesign: http://files.pine64.org/doc/rockpro64/RockPro64_Boardoutline Model.pdf
Expansions-Schnittstelle: http://files.pine64.org/doc/rockpro64/Rockpro64 Pi-2 Connector ver0.2.png

SOC:
http://opensource.rock-chips.com/wiki_RK3399
http://rockchip.wikidot.com/linux-user-guide
http://opensource.rock-chips.com/wiki_Boot_option

Github:
https://github.com/ayufan-rock64/
https://github.com/rockchip-linux
Im Fediverse -> @FrankM@nrw.social
1. NanoPi R5S
2. Quartz64 Model B, 4GB RAM
3. Quartz64 Model A, 4GB RAM
4. RockPro64 v2.1
1 Antwort Letzte Antwort
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FrankM
schrieb am zuletzt editiert von

#2

LPDDR4

Der Speicher ist LPDDR4, der laut einer Samsung Webseite 1,2x schneller als LPDDR3 sein soll und 37% weniger Strom verbrauchen soll.

The new feature is the LPDDR4 upgrade from LPDDR3, this increase overall system memory and IO (DMA) performance. However, the LPDDR4 driver still in tuning stage, the performance increase still not yet calculated. This ROCKPro64 is the first and only RK3399 SBC in current market using LPDDR4.
Im Fediverse -> @FrankM@nrw.social
1. NanoPi R5S
2. Quartz64 Model B, 4GB RAM
3. Quartz64 Model A, 4GB RAM
4. RockPro64 v2.1
1 Antwort Letzte Antwort
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FrankM
schrieb am zuletzt editiert von FrankM

#3
SPI Boot Flash

Some of PINE64 devices, such as the Rock64 and SOPine, are equipped with SPI Flash. This allows users to flash u-boot onto the SPI and boot from an external USB 2.0 or USB 3.0 SSD/HDD/thumb-drive, thereby forgoing using eMMC or an microSD card.
Quelle: http://wiki.pine64.org/index.php/NOOB#Flashing_u-boot_to_SPI_Flash

Kurze Erklärung:

Serial EEPROMs are low power, non-volatile memory devices with robust operating ranges, small size and byte alterability, making them ideal for data and program storage. Serial EEPROMs can be written more than 1 Million times.
Quelle: https://www.microchip.com/design-centers/memory

Also für Laien, so ähnlich wie Euer BIOS in einem normalen Rechner. Dort liegt dann der u-boot, das Bootprogramm. Vorteil, man braucht dann keine SD-Karte mehr zum Booten, sondern kann direkt von z.B. einer HDD oder SDD booten.

Boot Reihenfolge:
- SPI flash
- eMMC (disable with jumper)
- microSD
- USB drive
- PXE
Quellen:
http://wiki.pine64.org/index.php/NOOB#Flashing_u-boot_to_SPI_Flash

linux-build/recipes/flash-spi.md at master · ayufan-rock64/linux-build

Rock64 Linux build scripts, tools and instructions - linux-build/recipes/flash-spi.md at master · ayufan-rock64/linux-build

GitHub (github.com)
Im Fediverse -> @FrankM@nrw.social
1. NanoPi R5S
2. Quartz64 Model B, 4GB RAM
3. Quartz64 Model A, 4GB RAM
4. RockPro64 v2.1
1 Antwort Letzte Antwort
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FrankM
schrieb am zuletzt editiert von

#4
Im Fediverse -> @FrankM@nrw.social
1. NanoPi R5S
2. Quartz64 Model B, 4GB RAM
3. Quartz64 Model A, 4GB RAM
4. RockPro64 v2.1
1 Antwort Letzte Antwort
0
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FrankM
schrieb am zuletzt editiert von FrankM

#5

Der ROCKPro64 würde sich ja evt. mal richtig gut als NAS machen. Gute Software vorausgesetzt. Da wäre aber auch noch wichtig, wie viel er an der Steckdose zieht. Hier mal was aus den Datenblättern.

Quelle: http://opensource.rock-chips.com/images/6/60/Rockchip_RK3399_Datasheet_V1.6-20170301.pdf
Im Fediverse -> @FrankM@nrw.social
1. NanoPi R5S
2. Quartz64 Model B, 4GB RAM
3. Quartz64 Model A, 4GB RAM
4. RockPro64 v2.1
1 Antwort Letzte Antwort
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FrankM
schrieb am zuletzt editiert von FrankM

#6

Der ROCKPro64 hat kein WLan / BT on Board. Dafür kann man ein Modul kaufen, was man direkt auf's SOC stecken kann.

PINE64 Community

PINE64 is a large, vibrant and diverse community and creates software, documentation and projects.

(www.pine64.org)

Kosten: 16$

Das Modul basiert auf einem AMPAK AP6356

Für mich praktisch, da ich WLan usw. im Normalfall nicht nutze.
Im Fediverse -> @FrankM@nrw.social
1. NanoPi R5S
2. Quartz64 Model B, 4GB RAM
3. Quartz64 Model A, 4GB RAM
4. RockPro64 v2.1
1 Antwort Letzte Antwort
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FrankM
schrieb am zuletzt editiert von

#7

Ein paar Bilder
Im Fediverse -> @FrankM@nrw.social
1. NanoPi R5S
2. Quartz64 Model B, 4GB RAM
3. Quartz64 Model A, 4GB RAM
4. RockPro64 v2.1
1 Antwort Letzte Antwort
0
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FrankM
schrieb am zuletzt editiert von

#8

Bericht der Zeitschrift Make.

Bastelrechner NanoPC-T4 und ROCKPro64: Mehr Raspi-Konkurrenz mit Rockchip

Leistungsfähige Raspi-Konkurrenten setzen zunehmend auf den Chip-Hersteller Rockchip. Zwei neue RK3399-Boards eröffnen die Alternative: kompakt oder günstig?

Make (www.heise.de)
Im Fediverse -> @FrankM@nrw.social
1. NanoPi R5S
2. Quartz64 Model B, 4GB RAM
3. Quartz64 Model A, 4GB RAM
4. RockPro64 v2.1
1 Antwort Letzte Antwort
0

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RockPro64 - Mainline Kernel 6.8.0-rc3
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Mainline 5.13.x
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Images 0.9.x
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0.9.16: gitlab-ci-linux-build-163 released
0.9.x 0.9.16: Bump kernel to 4.4.197, 0.9.15: Bump kernel to 4.4.193, 0.9.14: Bump kernel to 4.4.190, 0.9.14: Fix Firefox video playback, 0.9.13: Bump sound volume for Pinebook Pro, 0.9.12: Fix LXDE for Rock64, 0.9.10: Fix support for power/standby LEDs for all boards,
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ROCKPro64 - Armbian nand-sata-install
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Ich habe heute, nachdem es einige Updates von Armbian gab, mal nachgeschaut ob ein spezieller Fehler verschwunden ist.
Und zwar geht es um das Resizen der Partion nachdem wir Armbian auf eine USB-HDD (USB3) installiert haben.

Ich setze dafür folgendes System ein.
Hardware ROCKPro64v2.0 4GB RAM SanDisk 240GB 2,5 Zoll HDD (nix tolles) Software Welcome to ARMBIAN 5.67.181217 nightly Debian GNU/Linux 9 (stretch) 4.4.167-rockchip64
Was sehe ich nach dem Reboot?
root@rockpro64:~# df -h Filesystem Size Used Avail Use% Mounted on udev 1.9G 0 1.9G 0% /dev tmpfs 388M 5.3M 383M 2% /run /dev/sda1 220G 1.3G 207G 1% / tmpfs 1.9G 0 1.9G 0% /dev/shm tmpfs 5.0M 4.0K 5.0M 1% /run/lock tmpfs 1.9G 0 1.9G 0% /sys/fs/cgroup tmpfs 1.9G 4.0K 1.9G 1% /tmp /dev/mmcblk0p1 58G 1.3G 57G 3% /media/mmcboot /dev/zram0 49M 3.0M 43M 7% /var/log tmpfs 388M 0 388M 0% /run/user/0
Korrekt die Größe angepasst!

Schnell mal den USB3 testen
root@rockpro64:~# sudo dd if=/dev/zero of=sd.img bs=1M count=4096 conv=fdatasync 4096+0 records in 4096+0 records out 4294967296 bytes (4.3 GB, 4.0 GiB) copied, 38.0723 s, 113 MB/s
Der Adapter
root@rockpro64:~# lsusb -vvv Bus 004 Device 002: ID 2109:0715 VIA Labs, Inc. Device Descriptor: bLength 18 bDescriptorType 1 bcdUSB 3.10 bDeviceClass 0 (Defined at Interface level) bDeviceSubClass 0 bDeviceProtocol 0 bMaxPacketSize0 9 idVendor 0x2109 VIA Labs, Inc. idProduct 0x0715 bcdDevice 1.31 iManufacturer 1 VLI Manufacture String iProduct 2 VLI Product String iSerial 3 000000123ADA bNumConfigurations 1 Configuration Descriptor: bLength 9 bDescriptorType 2 wTotalLength 121 bNumInterfaces 1 bConfigurationValue 1 iConfiguration 0 bmAttributes 0x80 (Bus Powered) MaxPower 224mA Interface Descriptor: bLength 9 bDescriptorType 4 bInterfaceNumber 0 bAlternateSetting 0 bNumEndpoints 2 bInterfaceClass 8 Mass Storage bInterfaceSubClass 6 SCSI bInterfaceProtocol 80 Bulk-Only iInterface 0 Endpoint Descriptor: bLength 7 bDescriptorType 5 bEndpointAddress 0x81 EP 1 IN bmAttributes 2 Transfer Type Bulk Synch Type None Usage Type Data wMaxPacketSize 0x0400 1x 1024 bytes bInterval 0 bMaxBurst 15 Endpoint Descriptor: bLength 7 bDescriptorType 5 bEndpointAddress 0x02 EP 2 OUT bmAttributes 2 Transfer Type Bulk Synch Type None Usage Type Data wMaxPacketSize 0x0400 1x 1024 bytes bInterval 0 bMaxBurst 15 Interface Descriptor: bLength 9 bDescriptorType 4 bInterfaceNumber 0 bAlternateSetting 1 bNumEndpoints 4 bInterfaceClass 8 Mass Storage bInterfaceSubClass 6 SCSI bInterfaceProtocol 98 iInterface 0 Endpoint Descriptor: bLength 7 bDescriptorType 5 bEndpointAddress 0x04 EP 4 OUT bmAttributes 2 Transfer Type Bulk Synch Type None Usage Type Data wMaxPacketSize 0x0400 1x 1024 bytes bInterval 0 bMaxBurst 0 Command pipe (0x01) Endpoint Descriptor: bLength 7 bDescriptorType 5 bEndpointAddress 0x85 EP 5 IN bmAttributes 2 Transfer Type Bulk Synch Type None Usage Type Data wMaxPacketSize 0x0400 1x 1024 bytes bInterval 0 bMaxBurst 15 MaxStreams 32 Data-in pipe (0x03) Endpoint Descriptor: bLength 7 bDescriptorType 5 bEndpointAddress 0x06 EP 6 OUT bmAttributes 2 Transfer Type Bulk Synch Type None Usage Type Data wMaxPacketSize 0x0400 1x 1024 bytes bInterval 0 bMaxBurst 15 MaxStreams 32 Data-out pipe (0x04) Endpoint Descriptor: bLength 7 bDescriptorType 5 bEndpointAddress 0x87 EP 7 IN bmAttributes 2 Transfer Type Bulk Synch Type None Usage Type Data wMaxPacketSize 0x0400 1x 1024 bytes bInterval 0 bMaxBurst 0 MaxStreams 32 Status pipe (0x02) Binary Object Store Descriptor: bLength 5 bDescriptorType 15 wTotalLength 70 bNumDeviceCaps 4 FIXME: alloc bigger buffer for device capability descriptors Device Status: 0x0000 (Bus Powered)
Ein lästiger Fehler weniger. 😉
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ROCKPro64 - Reset & Power Taster (extern)
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Neue Artikel im Pine64 Shop (August 2018)
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Neue Artikel im Pine64 Shop
ABS Gehäuse https://www.pine64.org/?product=rockpro64-abs-enclosure Gehäuse für einen ROCKPro64 und einen LCD-Bildschirm https://www.pine64.org/?product=rockpro64-playbox-enclosure
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nodejs & NodeBB
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stretch-minimal-rockpro64
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Mal ein Test was der Speicher so kann.
rock64@rockpro64:~/tinymembench$ ./tinymembench tinymembench v0.4.9 (simple benchmark for memory throughput and latency) ========================================================================== == Memory bandwidth tests == == == == Note 1: 1MB = 1000000 bytes == == Note 2: Results for 'copy' tests show how many bytes can be == == copied per second (adding together read and writen == == bytes would have provided twice higher numbers) == == Note 3: 2-pass copy means that we are using a small temporary buffer == == to first fetch data into it, and only then write it to the == == destination (source -> L1 cache, L1 cache -> destination) == == Note 4: If sample standard deviation exceeds 0.1%, it is shown in == == brackets == ========================================================================== C copy backwards : 2812.7 MB/s C copy backwards (32 byte blocks) : 2811.9 MB/s C copy backwards (64 byte blocks) : 2632.8 MB/s C copy : 2667.2 MB/s C copy prefetched (32 bytes step) : 2633.5 MB/s C copy prefetched (64 bytes step) : 2640.8 MB/s C 2-pass copy : 2509.8 MB/s C 2-pass copy prefetched (32 bytes step) : 2431.6 MB/s C 2-pass copy prefetched (64 bytes step) : 2424.1 MB/s C fill : 4887.7 MB/s (0.5%) C fill (shuffle within 16 byte blocks) : 4883.0 MB/s C fill (shuffle within 32 byte blocks) : 4889.3 MB/s C fill (shuffle within 64 byte blocks) : 4889.2 MB/s --- standard memcpy : 2807.3 MB/s standard memset : 4890.4 MB/s (0.3%) --- NEON LDP/STP copy : 2803.7 MB/s NEON LDP/STP copy pldl2strm (32 bytes step) : 2802.1 MB/s NEON LDP/STP copy pldl2strm (64 bytes step) : 2800.7 MB/s NEON LDP/STP copy pldl1keep (32 bytes step) : 2745.5 MB/s NEON LDP/STP copy pldl1keep (64 bytes step) : 2745.8 MB/s NEON LD1/ST1 copy : 2801.9 MB/s NEON STP fill : 4888.9 MB/s (0.3%) NEON STNP fill : 4850.1 MB/s ARM LDP/STP copy : 2803.8 MB/s ARM STP fill : 4893.0 MB/s (0.5%) ARM STNP fill : 4851.7 MB/s ========================================================================== == Framebuffer read tests. == == == == Many ARM devices use a part of the system memory as the framebuffer, == == typically mapped as uncached but with write-combining enabled. == == Writes to such framebuffers are quite fast, but reads are much == == slower and very sensitive to the alignment and the selection of == == CPU instructions which are used for accessing memory. == == == == Many x86 systems allocate the framebuffer in the GPU memory, == == accessible for the CPU via a relatively slow PCI-E bus. Moreover, == == PCI-E is asymmetric and handles reads a lot worse than writes. == == == == If uncached framebuffer reads are reasonably fast (at least 100 MB/s == == or preferably >300 MB/s), then using the shadow framebuffer layer == == is not necessary in Xorg DDX drivers, resulting in a nice overall == == performance improvement. For example, the xf86-video-fbturbo DDX == == uses this trick. == ========================================================================== NEON LDP/STP copy (from framebuffer) : 602.5 MB/s NEON LDP/STP 2-pass copy (from framebuffer) : 551.6 MB/s NEON LD1/ST1 copy (from framebuffer) : 667.1 MB/s NEON LD1/ST1 2-pass copy (from framebuffer) : 605.6 MB/s ARM LDP/STP copy (from framebuffer) : 445.3 MB/s ARM LDP/STP 2-pass copy (from framebuffer) : 428.8 MB/s ========================================================================== == Memory latency test == == == == Average time is measured for random memory accesses in the buffers == == of different sizes. The larger is the buffer, the more significant == == are relative contributions of TLB, L1/L2 cache misses and SDRAM == == accesses. For extremely large buffer sizes we are expecting to see == == page table walk with several requests to SDRAM for almost every == == memory access (though 64MiB is not nearly large enough to experience == == this effect to its fullest). == == == == Note 1: All the numbers are representing extra time, which needs to == == be added to L1 cache latency. The cycle timings for L1 cache == == latency can be usually found in the processor documentation. == == Note 2: Dual random read means that we are simultaneously performing == == two independent memory accesses at a time. In the case if == == the memory subsystem can't handle multiple outstanding == == requests, dual random read has the same timings as two == == single reads performed one after another. == ========================================================================== block size : single random read / dual random read 1024 : 0.0 ns / 0.0 ns 2048 : 0.0 ns / 0.0 ns 4096 : 0.0 ns / 0.0 ns 8192 : 0.0 ns / 0.0 ns 16384 : 0.0 ns / 0.0 ns 32768 : 0.0 ns / 0.0 ns 65536 : 4.5 ns / 7.2 ns 131072 : 6.8 ns / 9.7 ns 262144 : 9.8 ns / 12.8 ns 524288 : 11.4 ns / 14.7 ns 1048576 : 16.0 ns / 22.6 ns 2097152 : 114.0 ns / 175.3 ns 4194304 : 161.7 ns / 219.9 ns 8388608 : 190.7 ns / 241.5 ns 16777216 : 205.3 ns / 250.5 ns 33554432 : 212.9 ns / 255.5 ns 67108864 : 222.3 ns / 271.1 ns