Best Motherboards for 3d Rendering – Gigabyte motherboard for rendering is 7 series motherboards are the one that offers dual onboard thunderbolt ports. This type of the motherboard can connect the 12 devices with 3 digital displays.
They allow their users to chain up to 12 devices with a bi-directional 10 GBPS data pipeline. They are fast and flexible and have the best connectivity criteria.
Intel C621 motherboard with quad strength graphics
This type of motherboard is important in the dual CPU motherboard for rendering.
It has up to 4-way NVIDIA and AMD crossfire X on customer demand. The
dual CPU OC tuning is essential for extreme performances.
It has super scalability and the best connectivity with U.2, M.2, and USB type 3.1 is built in this processor. It also has excellent power efficiency. ASUS WS C621E has four dual graphic cards. This motherboard is best for 3d rendering because it has high power consumption.
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1.ASUS ROG Crosshair VI Hero
- Powered by AMD Ryzen AM4, 7th generation Athlon and HD 2000 series processors to maximize connectivity and speed with NVMe M.2, onboard 802.11AC WIFI, front panel USB 3.1 and gigabit LAN
- 5-Way Optimization featuring Auto-Tuning and FanXpert 4 provides automatic overclocking profiles for maximum OC performance while AIO and watercooling headers deliver dynamic system cooling
Asus never does half measures with its Crosshair mainboards. As always, the component giant aimed for the far reaches of the market with its ROG Crosshair VI Hero ($255), its flagship motherboard for AMD’s powerful Ryzen 7 processors. Naturally, this Socket AM4 board is in Asus’ Republic of Gamers (ROG) series, which is a signal to expect a wealth of enthusiast features and more-than-passing support for overclocking.
Bearing AMD’s high-end X370 chipset and a slick RGB-lighting arrangement, this board will garner plenty of attention from gamers looking to build PCs around a new AMD Ryzen 7 1800X, or one of the lesser (but still potent) Ryzen 7 or 5 CPUs.back to menu ↑
2.ASUS ROG X570
- AMD AM4 socket: ready for 2nd, and 3rd Gen AMD Ryzen processors and up to two M. 2 drives, USB 3. 2 Gen2, and AMD StoreMI to maximize connectivity and speed.
- Comprehensive thermal design: active PCH heatsink, M. 2 aluminum heatsink and ROG cooling zone.
Motherboard designers typically go for obvious choices: When AMD announced that its latest platform would support one NVMe M.2 drive from the CPU and up to 16 high-speed connections from the X570 PCH, it was obvious that most manufacturers would deploy twelve of those PCH lanes as a second and third M.2 interface plus a PCIe x4 slot.
Those designers were then left to figure out whether to use those final four lanes for SATA, USB3 or additional PCIe. And that’s where lane sharing that disables one interface to enable another begins. Asus took a different track in its ROG Strix X570-E Gaming: It has only two M.2 slots total.back to menu ↑
3.ASUS ROG Crosshair VIII
- AMD AM4 socket: Ready for 2nd, 3rd Gen AMD Ryzen processors and 3rd Gen AMD Ryzen processors
- Comprehensive thermal design: Passive chipset heatsink, M.2 aluminum heatsinks and ROG Water Cooling Zone.
The Asus X570 motherboard lineup includes options from the TUF, Prime, Strix, WS (Workstation), and ROG lines in ATX form-factor only (currently). If you are looking for an ITX board, it will have to be from Gigabyte or ASRock for now, while Micro-ATX boards can be found in Asus, MSI, ASRock, and Gigabyte lineups.
The OG Crosshair VIII Formula leads the pack, followed by the Hero and WS, with the Strix, Prime and TUF lines mixed in on the way down the product stack. With a total of 10 motherboards in its lineup, Asus has enough options to suit most builds.
The Asus ROG Crosshair VIII Hero Wi-Fi’s price point lands it in the upper mid-range of all X570 boards. The overall experience with the board was positive, as stock testing completed without a hitch and performance was as expected, with results right around the other boards.back to menu ↑
4.ASUS ROG Strix B550-F
- AMD AM4 Socket and PCIe 4. 0: The perfect pairing for Zen 3 Ryzen 5000 & 3rd Gen AMD Ryzen CPUs
- Robust Power Design: 12 plus 2 DrMOS power stages with high-quality alloy chokes and durable capacitors provide reliable power for the last AMD high-count-core CPUs
Sitting second from the top of Asus’ B550 motherboards, the B550-F Gaming Wi-Fi includes 14-phase power delivery, 2.5 GbE LAN, integrated Wi-Fi 6 AX200, two M.2 slots (each with a heatsink), six SATA ports and premium audio, among other features.
In our testing, the B550-F Gaming Wi-Fi performed well, matching the other boards we’ve tested so far. We didn’t come across anything out of the ordinary during our stock runs. With optimized defaults set, the B550-F Gaming Wi-Fi had no issues boosting to the factory 4.6 GHz clock speed.
Overclocking the 12 core 24 thread Ryzen 9 3900X also went without an issue. Our sample was able to push all cores and threads on the CPU to 4.3 GHz, while running our 4×8 GB RAM KIT at DDR4 3600 with Infinity Fabric 1:1 to the memory speed.back to menu ↑
5.ASUS ROG Zenith II Extreme Alpha
- 1. Ready for AMD 3rd Gen Ryzen Threadripper Processors: PCIe 4. 0 ready, 4733Mhz memory OC performance, with up to five M. 2 drives and USB3. 2 Gen2x2 support
- 2. Robust power delivery: Optimized power solution with 16 Infineon TDA21490 teamed up power stages, ProCool II power connectors, microfine alloy chokes and 10K capacitors
Asus’ original Zenith II Extreme seemed like one of the best TRX40 models when we tested it, but it was tough to justify its price.
Like the audio and I/O controllers, every connector on the Zenith II Extreme Alpha appears to be carried over from its predecessor, from the USB BIOS Flashback and CLR_CMOS buttons as well asthe USB Type-C and Type-C 2.2 ports on the I/O panel, to the collection of advanced buttons and switches in the forward bottom corner described in our earlier review.
Even the Live Dash OLED panel above the I/O ports, and the x16/x8/x16/x8 PCIe slot spacing that favors two triple-slot graphics cards, remain.back to menu ↑
3d rendering is the process of making and creating two-dimensional images. The generated images are based on the data which tyrannize the color and texture of a certain object in the image.
The term rendering is firstly observed in 1960 when William Fetter portrayal a pilot to stimulate the space needs. After this step in 1963, Ivan Sutherland created a sketchpad. In 1975 a researcher Martin Newell created a 3D test model of “Utah teapot” which fortunately become a standard render.