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Socket TR4
Socket TR4
Socket TR4
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Socket TR4
TypeLGA-ZIF
Chip form factorsFlip-chip
Contacts4094
FSB protocolPCI Express, Infinity Fabric
Processor dimensions58.5mm x 75.4mm
4410.9 mm2
ProcessorsRyzen Threadripper:
SuccessorsTRX4
Memory supportDDR4
This article is part of the CPU socket series

Socket TR4, also known as Socket SP3r2, is a zero insertion force land grid array (LGA) CPU socket designed by AMD supporting its first- and second-generation Zen-based Ryzen Threadripper desktop processors,[1][2] launched on August 10, 2017[3] for the high-end desktop and workstation platforms. It was succeeded by Socket sTRX4 for the third generation of Ryzen Threadripper processors.

TR4 is AMD's second LGA socket for a consumer product after the short lived Socket 1207 FX.[4][5] It is physically identical to, but electrically incompatible with both AMD's server Socket SP3, and TR4's successor, Socket sTRX4.[3][6]

While the SP3 server socket does not require a chipset, instead utilizing a system-on-a-chip design, TR4 and its successor HEDT sockets require a chipset to unlock the features of the CPU. For TR4, the AMD X399 chipset was released, which allows a total of 64 PCIe 3.0 lanes for quad SLI/CrossFire configurations.[7]

The socket is made by both Foxconn and Lotes.[8]

See also

[edit]

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Socket TR4

View on Grokipedia
from Grokipedia
Socket TR4 is a land grid array (LGA) central processing unit (CPU) socket with 4,094 pins, developed by Advanced Micro Devices (AMD) for its first- and second-generation Ryzen Threadripper high-end desktop (HEDT) processors. Introduced in August 2017 alongside the initial Threadripper lineup, the socket pairs exclusively with the AMD X399 chipset to enable extreme multi-core performance for content creation, gaming, and professional workloads. The Socket TR4 platform emphasizes scalability and high-bandwidth connectivity, supporting quad-channel DDR4 memory with optional error-correcting code (ECC) for enhanced reliability in demanding applications. It provides up to 64 PCIe 3.0 lanes directly from the CPU (60 available for peripherals after reserving 4 for chipset communication) for multi-GPU configurations via or SLI, plus 8 PCIe Gen 2.0 lanes from the chipset for storage and peripherals. Storage options include NVMe and up to 12 ports with 0, 1, and 10 support, while USB connectivity features up to 6 USB 2.0 ports, 2 USB 3.1 Gen 2 ports, and 14 USB 3.1 Gen 1 ports. Compatible with processors offering up to 32 cores and 64 threads—such as the Threadripper 2990WX—Socket TR4 also supports (though AMD's warranty excludes damage from it) and technologies like AMD StoreMI for storage optimization. The socket's large form factor requires specialized cooling solutions, and a update is often needed for second-generation processor support on motherboards originally designed for the first generation. Overall, Socket TR4 represented a significant advancement in 's HEDT offerings at the time, bridging desktop and server-like capabilities before being succeeded by later sockets like sTRX4 for third-generation Threadripper CPUs.

History

Development

AMD developed Socket TR4 as a derivative of the existing Socket SP3, which was designed for its Epyc server processors, to leverage established server infrastructure and minimize development expenses for the niche high-end desktop (HEDT) market. This approach allowed AMD to adapt proven server-grade pinout and mechanical designs while tailoring the socket for consumer workloads, avoiding the full cost of creating an entirely new interface for a smaller segment. The socket was first announced on May 16, 2017, and launched alongside the first-generation Ryzen Threadripper processors on August 10, 2017, as AMD extended its Zen microarchitecture into the high-end desktop space to compete with Intel's offerings. This initiative aimed to deliver multi-core performance previously reserved for servers to enthusiast users, with Socket TR4 enabling up to 64 PCIe lanes and quad-channel memory support optimized for desktop applications. Key engineering choices involved adjusting pin assignments from the SP3 baseline. These modifications ensured compatibility with the while maintaining the 4094-pin LGA form factor for robust power delivery. Primary manufacturing was handled by Interconnect Technology and Lotes Co., Ltd., both established suppliers of 's LGA sockets. Socket TR4 represented AMD's broader transition to land grid array (LGA) designs for consumer platforms, serving as the second such socket following the brief Socket 1207 FX introduced in 2006 for dual-processor FX systems. This shift from earlier (PGA) sockets like AM2 and AM3 facilitated better scalability for high-power CPUs in desktop environments.

Release

Socket TR4 was officially introduced to the market on August 10, 2017, coinciding with the availability of the first-generation AMD Threadripper processors and compatible X399 chipset motherboards. This launch marked AMD's entry into the high-end desktop (HEDT) segment, providing enthusiasts and professionals with access to up to 16-core configurations at competitive price points. The platform saw expansion in August 2018 with the release of second-generation Threadripper processors based on the Zen+ architecture, which utilized the same TR4 socket for seamless integration. These processors, offering up to 32 cores, maintained with existing X399 motherboards, though a update was required to enable support on first-generation boards. Support for the socket effectively ended after the 2018 second-generation launch, as subsequent Threadripper generations transitioned to revised socket designs without further TR4 compatibility.

Design

Physical Design

Socket TR4 is a (LGA) socket with 4094 nickel- and gold-plated pins, enabling high-density electrical contacts between the processor and . The design incorporates a (ZIF) mechanism, which facilitates easy CPU installation and removal by eliminating the need to apply pressure directly to the delicate pins during seating. This is implemented via a flip-up retention cover and bracket system, where the CPU—held in an orange plastic carrier—is placed into a tray and lowered into the socket without resistance; the cover is then secured using three screws tightened in sequence (1→2→3) to apply uniform clamping pressure across the package. The processor package for Socket TR4 measures 58.5 mm × 75.4 mm, yielding an area of 4410.9 mm² and establishing it as one of the largest form factors among high-end desktop CPU sockets. This expansive size accommodates the (MCM) architecture of Ryzen Threadripper processors, which integrate multiple dies on a single substrate. The socket derives its physical layout from the server-grade Socket SP3, adapting it for desktop use while maintaining identical overall dimensions. Socket TR4 employs a flip-chip processor form factor, in which the CPU die is directly attached face-down to the organic substrate using controlled collapse chip connection (C4) bumps, optimizing and heat dissipation pathways from the die to the integrated heat spreader (IHS). The retention mechanism includes reinforced brackets and mounting hardware designed to support substantial heatsinks capable of handling the elevated (TDP) ratings of Threadripper CPUs, often exceeding 250 W, ensuring stable contact under heavy cooling loads. Asymmetrical screw emplacements on the socket (65.2 mm on one side and 46 mm on the other) further enable compatibility with oversized air and cooling solutions tailored to the socket's rectangular footprint.

Electrical Design

Socket TR4 employs a (LGA) design with 4094 pins dedicated to power, ground, data, and control signals, enabling high-bandwidth communication for AMD's Threadripper processors. These pins support advanced features tailored for consumer high-end desktop applications, including reservations for capabilities such as Precision Boost Overdrive, which allows users to extend power and thermal limits beyond stock configurations for enhanced performance. The socket's power delivery architecture is engineered to handle demanding workloads, supporting thermal design power (TDP) ratings up to 250 W, as seen in models like the Ryzen Threadripper 2990WX. This requires motherboards equipped with robust voltage regulation modules (VRMs), typically featuring multi-phase designs capable of delivering stable power under sustained high loads, ensuring reliability during intensive multi-threaded operations. Signaling protocols in Socket TR4 integrate as the primary mechanism for I/O connectivity, with dedicated pathways facilitating CPU-to-chipset communication. Complementing this is 's Infinity Fabric interconnect, which enables efficient multi-chiplet communication within Threadripper CPUs, allowing seamless data transfer between core complexes and I/O dies to optimize overall coherence and latency. Despite its physical similarity to the server-oriented Socket SP3, Socket TR4 is electrically incompatible due to consumer-specific pin reassignments that prioritize and desktop-oriented features over enterprise reliability protocols. This design choice ensures that Threadripper processors cannot be cross-installed in SP3 systems, preventing potential damage from mismatched signaling.

Specifications

Memory Support

Socket TR4 platforms feature a quad-channel DDR4 designed to deliver high bandwidth for high-end desktop and applications. This configuration supports up to two s per channel, resulting in a total of eight DIMM slots across compatible X399 motherboards, allowing for balanced population to maximize performance. The official memory speed support is DDR4-2666 MHz, providing a theoretical maximum bandwidth of approximately 85 GB/s in quad-channel mode. However, due to the unlocked nature of Threadripper processors, users can overclock memory to higher speeds, such as 3600 MHz or beyond, on s with robust voltage regulation and options, though stability depends on the specific hardware and cooling. ECC compatibility is a key feature for professional use, with support for unbuffered ECC DDR4 modules to enable , alongside standard non-ECC options for consumer setups; this is available across first- and second-generation Threadripper processors when enabled by the . At launch, the maximum capacity was 256 GB, configured with two 32 GB modules per channel, but higher-density modules later allowed expansions up to 512 GB or more. The is integrated directly into the CPU die within the architecture, facilitating low-latency access and optimized bandwidth allocation across the four channels to support memory-intensive tasks like and scientific .

I/O Capabilities

Socket TR4 provides robust expansion primarily through its PCIe connectivity, enabling high-bandwidth peripherals for professional workloads such as and multi-GPU rendering. The socket's Ryzen Threadripper processors deliver 64 PCIe 3.0 lanes directly from the CPU, with 4 lanes dedicated to the link for system communication, leaving up to 60 lanes available for GPUs, storage, and other devices. This configuration supports bifurcation options like x16, x8, x4, or x2 per lane group, allowing flexible allocation across multiple slots on compatible X399 motherboards. Multi-GPU setups are a key strength, with support for up to four NVIDIA SLI or AMD CrossFire configurations via dedicated x16 slots, leveraging the ample PCIe lanes to maintain full bandwidth for graphics-intensive applications without significant performance bottlenecks. For storage, the platform accommodates NVMe devices in U.2 and M.2 form factors, connected directly to the CPU's PCIe lanes for low-latency access. AMD's NVMe RAID implementation enables configurations up to RAID levels 0, 1, and 10, combining multiple SSDs for enhanced speed or redundancy in demanding data workflows. Integrated USB capabilities include up to 8 USB 3.1 Gen 1 (5 Gbps) ports provided by the Threadripper CPU itself, supplementing the X399 chipset's additional ports for a total of up to 14 USB 3.1 Gen 1, 2 USB 3.1 Gen 2, and 6 USB 2.0 across the platform. Notably, Socket TR4 lacks native PCIe 4.0 support, remaining limited to PCIe 3.0 throughout its lifecycle with first- and second-generation Threadripper processors, which prioritizes broad compatibility over the higher speeds introduced in later sockets.

Compatibility

Supported Processors

Socket TR4 supports Threadripper processors from the first and second generations, based on the and architectures, respectively. These high-end desktop (HEDT) CPUs were designed for demanding workloads such as , , and scientific computing, offering high core counts and extensive connectivity. All compatible processors feature unlocked multipliers for manual , 64 PCIe 3.0 lanes for expansions like GPUs and storage, and quad-channel DDR4 memory support up to 2666 MT/s for the first generation and 2933 MT/s for the second generation. The first-generation Ryzen Threadripper processors, codenamed and launched in , include three models targeting enthusiasts and professionals seeking multi-threaded performance on a single socket. These 14 nm Zen-based CPUs introduced groundbreaking core scaling for desktops at the time, with up to 16 cores. Key models are summarized below:
ModelCores/ThreadsBase ClockBoost ClockTDPLaunch Price
1900X8/163.8 GHz4.0 GHz180 W$549
1920X12/243.5 GHz4.0 GHz180 W$799
1950X16/323.4 GHz4.0 GHz180 W$999
These processors emphasize balanced performance, with the 1950X serving as the for maximum parallelism. The second-generation Threadripper processors, codenamed Colfax and released in 2018, build on the Zen+ architecture with a refined 12 nm process for improved efficiency and higher clocks. They expand core counts up to 32, targeting even more intensive professional applications while maintaining with Socket TR4 via the X399 ( updates may be required). The full lineup includes enthusiast-oriented X-series models (2920X, 2950X) and workstation-focused WX-series variants (2970WX, 2990WX). Representative models include:
ModelCores/ThreadsBase ClockBoost ClockTDPLaunch Price
2920X12/243.5 GHz4.3 GHz180 W$649
2950X16/323.5 GHz4.3 GHz180 W$899
2970WX24/483.0 GHz4.2 GHz250 W$1,299
2990WX32/643.0 GHz4.2 GHz250 W$1,799
The WX models prioritize sustained multi-threaded workloads with larger caches and higher TDPs for thermal headroom. Socket TR4 compatibility ends with the second-generation processors in 2018; subsequent Threadripper generations (starting with the third, based on ) transitioned to the sTRX4 socket and later sWRX8 for PRO variants, introducing PCIe 4.0 and higher core densities without backward support for TR4 platforms.

Chipsets and Motherboards

The X399 chipset serves as the primary and exclusive platform for Socket TR4 motherboards, enabling support for both first-generation Threadripper processors (1000 series) and second-generation models (2000 series) through firmware updates. Released in alongside the initial Threadripper launch, the X399 provides a high-bandwidth foundation for high-end desktop (HEDT) workloads, emphasizing expandability for applications like and multi-GPU configurations. Key features of the X399 include six native USB 2.0 ports for basic connectivity, 8 additional PCIe Gen 2.0 lanes from the for peripherals and storage to support a total of 66 PCIe Gen 3.0 lanes and 8 PCIe Gen 2.0 lanes, and built-in NVMe capabilities for enhanced solid-state drive performance. These elements allow for flexible I/O expansion without relying solely on processor resources, making it suitable for demanding setups involving multiple storage devices or add-in cards. Popular motherboard implementations based on the X399 include the Zenith Extreme, which features eight DDR4 memory slots for quad-channel operation and five PCIe slots to accommodate extensive expansion. The Aorus Xtreme offers integrated connectivity and dual slots for high-speed NVMe storage, catering to users seeking wireless networking alongside robust storage options. Similarly, the MSI X399 Gaming Pro Carbon incorporates RGB lighting for aesthetic customization and enhanced audio subsystems, appealing to gaming-oriented HEDT builds. Upgrade paths for Socket TR4 platforms are limited, with no direct successor socket or chipset within the TR4 ecosystem; transitioning to third-generation Threadripper processors requires adopting the newer sTRX4 socket and TRX40 chipset, necessitating a full platform replacement including and potentially other components. For high-TDP processors like the 2990WX (rated at 250W), motherboards demand robust modules (VRMs) with , often including dedicated heatsinks or fan-assisted designs to prevent thermal throttling under sustained loads exceeding 300W in overclocked scenarios. Motherboard manufacturers, such as , provided optional VRM cooling kits for the 2990WX to ensure stability in intensive workloads.

Comparisons

With Socket SP3

Socket TR4 and Socket SP3 exhibit identical physical characteristics, both employing a (LGA) configuration with 4,094 pins and dimensions measuring 79.9 mm by 120.3 mm. This shared mechanical design stems from their common origins in AMD's architecture roadmap, where TR4—also designated as SP3r2—emerged as a variant adapted for high-end desktop applications from the server-focused SP3 foundation. Although the physical similarity enables potential mechanical interchangeability, such as shared cooler mounting points, AMD explicitly advises against cross-usage due to underlying incompatibilities. Electrically, Socket TR4 diverges from SP3 through pin reassignments that prioritize consumer-oriented features, including support for via unlocked multipliers and base clock adjustments, which are absent in the server-centric SP3. TR4 omits certain server-specific signals, such as those dedicated to advanced (RAS) functions, while reallocating pins for additional desktop I/O like extra USB controllers. These modifications reflect TR4's role as a cost-optimized , reducing complexity for high-end desktop (HEDT) workloads compared to SP3's enterprise demands. The market positioning further underscores their divergence: Socket SP3 powers AMD's server processors with octa-channel DDR4 memory support and up to 128 PCIe lanes for data center scalability, whereas TR4 targets HEDT users with quad-channel DDR4 and 64 PCIe lanes optimized for creative and computational tasks. Despite these tailored differences, attempting to install an SP3-compatible processor in a TR4 —or vice versa—poses significant risks, including potential damage from mismatched and signaling protocols that could lead to short circuits or component failure. This lack of cross-compatibility ensures platform integrity but highlights TR4's evolution as a specialized, consumer-derived branch of the original server socket lineage.

With Socket sTRX4

Socket sTRX4, also known as SP3r3, serves as the direct successor to Socket TR4, maintaining continuity in physical design with the same 4094-pin (LGA) configuration and identical socket dimensions to ensure compatibility with existing cooling solutions and layouts. However, it introduces key electrical enhancements, notably support for PCIe 4.0, which doubles the bandwidth per lane compared to the PCIe 3.0 standard used in TR4 platforms. This generational upgrade enables sTRX4 to support AMD's architecture for third-generation Threadripper processors, providing up to 64 CPU PCIe 4.0 for doubled overall bandwidth in high-end desktop configurations, alongside native support for DDR4-3200 memory speeds across four channels. In contrast, TR4 platforms were limited to PCIe 3.0 x64 and DDR4 speeds up to 2666 MHz natively, restricting in bandwidth-intensive workloads like multi-GPU rendering or large-scale storage arrays. Despite the form factor similarities, Socket TR4 and sTRX4 are electrically incompatible, as TR4 processors cannot operate in sTRX4 sockets due to differences in pin assignments, requirements, and power delivery specifications; the reverse incompatibility also holds, preventing sTRX4 CPUs from functioning on TR4 motherboards. The platform transition to sTRX4 is accompanied by the TRX40 chipset, which succeeds the X399 used with TR4 and delivers expanded I/O capabilities, including up to 12 native USB 3.2 Gen 2 ports for faster peripheral connectivity and a total of 88 PCIe 4.0 lanes across the system. This shift enhances overall platform versatility for professional workstations, building on TR4's foundation while addressing its I/O limitations. Introduced in November 2019 alongside the third-generation Ryzen Threadripper series, Socket sTRX4 effectively signaled the end of the TR4 era, rendering it obsolete for new high-performance builds as users migrated to the improved architecture for future-proofing.

References

  1. https://www.techpowerup.com/234393/underside-of-amd-ryzen-threadripper-pictured
  2. https://www.amd.com/en/newsroom/press-releases/2017-8-10-amd-launches-the-highest-performance-desktop-proce.html
  3. https://www.amd.com/en/products/processors/chipsets/str4.html
  4. https://www.amd.com/en/newsroom/press-releases/2018-8-6--world-record-breaking-2nd-generation-amd-ryzen-t.html
  5. https://en.wikichip.org/wiki/amd/packages/socket_tr4
  6. https://videocardz.com/newz/pin-layouts-show-differences-between-amd-sp3-and-tr4-sockets
  7. https://en.wikichip.org/wiki/amd/packages/socket_sp3
  8. https://en.wikichip.org/wiki/amd/List_of_AMD_CPU_sockets
  9. https://wccftech.com/amd-ryzen-threadripper-review-roundup-x399-launch/
  10. https://wccftech.com/amd-ryzen-threadripper-cpu-launch-august/
  11. https://ir.amd.com/news-events/press-releases/detail/844/world-record-breaking-2nd-generation-amd-ryzen-t.html
  12. https://hothardware.com/news/how-to-install-amd-ryzen-threadripper-x399-motherboard
  13. https://www.asrock.com/microsite/AMDX399CPU/index.asp
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  17. https://www.asrock.com/news/index.us.asp?id=3672
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  19. https://www.asrockrack.com/general/productdetail.asp?Model=X399D8A-2T
  20. https://www.gigabyte.com/Motherboard/X399-DESIGNARE-EX-rev-10
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  27. https://rog.asus.com/motherboards/rog-zenith/rog-zenith-extreme-model/spec/
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