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Socket 479
Socket 479
Socket 479
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Socket 479
TypePGA-ZIF
Chip form factorsFlip-chip pin grid array (FC-PGA2)
Contacts479 on the socket, 478 or 479 pins on the processor, 478 contacts used
FSB protocolAGTL+
FSB frequency400 MT/s, 533 MT/s
ProcessorsIntel Pentium M
Intel Celeron M
VIA C7-M
PredecessorSocket 495
SuccessorSocket M
This article is part of the CPU socket series

Socket 479 (mPGA479M) is a CPU socket used by some Intel microprocessors. It is primarily used for Pentium M and Celeron M mobile processors normally found in laptops; a similar yet electrically incompatible version of Socket 479 is also used for Tualatin-M Mobile Celeron and Pentium III processors.[1] The official naming by Intel is μFCPGA and μPGA479M.

Technical specifications

[edit]
An Asus CT-479 adapter
CT-479 installed on ASUS P4GPL-X motherboard

Socket 479 has 479 pin holes. Pentium M processors in PGA package have 479 pins that plug into this zero insertion force socket. Only 478 pins are electrically connected (B2 is reserved and "depopulated on the Micro-FCPGA package").[2]

Although mechanically similar, Socket 478 has one pin fewer, making it impossible to use a Pentium M processor in a Socket 478 board. For this reason, some manufacturers like Asus have made drop-in boards (e.g. CT-479) which allow the use of Socket 479 processors in Socket 478 boards.[3] Conversely, it is impossible to use any Socket 478 desktop Celeron and Pentium 4 processors in a Socket 479 board as they are electrically incompatible with Socket 479 despite being mechanically pin-compatible with it. For the same reason, Celeron M and Pentium M processors are pin-compatible but electrically incompatible with Pentium III-based Socket 479 boards.[1]

Chipsets which employ this socket for the Pentium M are the Intel 855GM/GME/PM, the Intel 915GM/GMS/PM and the VIA family of chipsets such as the VN800. While the Intel 855GME chipset supports all Pentium M CPU's, the Intel 855GM chipset does not officially support 90 nm 2MB L2 cache (Dothan core) models (even though it works, it only runs at 400 MT/s FSB; some users were able to overclock the FSB to 533 MT/s on 855GM/GME/PM chipsets to support 90 nm 2MB L2 cache Dothan cores).[4] The other difference is the 855GM chipset graphics core runs at 200 MHz while the 855GME runs at 250 MHz.

In 2006, Intel released the successor to Socket 479 with a revised pinout for its Core processor, called Socket M. Socket M supports a 667 MT/s FSB with the Intel 945PM/945GM chipsets. This socket has the placement of one pin changed from the Pentium M version of Socket 479; Socket M processors will physically fit into a Socket 479, but are electrically incompatible with most versions of Socket 479 (except using ATI north bridge RC415MD).[unreliable source?]

Socket and naming confusion

[edit]

There exist multiple electrically incompatible, but mechanically compatible processor families that are available in PGA packages using Socket 479 or variants thereof:[1]

Each of these above-mentioned processor families have CPU packages that are mechanically similar yet are not electrically compatible with each other, and therefore accidentally inserting them into the wrong socket configurations will not work or may result in damage to the processor and/or the motherboard.[1] Even Intel's CPU specifications seem to be not clear enough on the distinction and instead use the package/socket designations PGA478 or PPGA478 for more than 1 of the above sockets.[5][6]

Perhaps adding yet more confusion, some of the PGA-based CPUs above are also available in a BGA (or more precisely, μBGA or even μFCBGA) package which has all of the 479 contacts (balls) populated. For these CPU variants, the Intel's CPU specifications use the designations BGA479,[5] PBGA479[6] or H-PBGA479.[7] It should be however pointed out that these designations denote rather the CPU package itself and not the socket, which the BGA variants do not use at all (they are intended to be directly soldered to the mainboard, e.g. in an embedded system). The non-BGA counterparts of these CPUs use any one of the above-mentioned sockets, not just the Socket 479.

See also

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References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Socket 479

View on Grokipedia
from Grokipedia
Socket 479, officially designated as the mPGA479M ( Pin Grid Array 479), is a (ZIF) developed by for mobile processors in computers. It features a 479-pin configuration with a 1.27 mm pitch in a 26x26 pin array, supporting Micro-FCPGA packages measuring 35.1 mm x 35.1 mm. Introduced in November 2001, the socket was designed as a low-cost, (SMT) solution to provide reliable mechanical and electrical connectivity for 's mobile CPU lineup. The socket accommodates a range of single- and dual-core mobile processors, including the series (based on and Dothan cores) with clock speeds from 900 MHz to 2.26 GHz and (FSB) frequencies up to 533 MHz, as well as later series such as M, Core Solo, and Core Duo. Electrical specifications include a maximum mating resistance of 25 mΩ, inductance below 3.0 nH, and capacitance under 1.0 pF per contact, with support for core voltages typically ranging from 0.8 V to 1.4 V depending on the processor. Mechanically, Socket 479 is engineered for durability in compact environments, with a maximum compressive load of 50 lbf and a socket weight not exceeding 14 grams, ensuring compatibility with thermal design powers (TDP) from 5 to 34 across supported CPUs. While phased out in favor of later sockets like Socket P by the mid-2000s, it played a key role in powering portable computing during the transition from to Core architectures, emphasizing energy efficiency and performance for mobile applications.

Overview

Introduction

Socket 479, also known as mPGA479M, is a 479-pin micro (mPGA) (ZIF) socket developed by specifically for mobile processors. This socket features a 1.27 mm pin pitch and mates with Micro Flip-Chip (Micro-FCPGA) packages, allowing for easy insertion and removal of the CPU without applying force to the pins. Introduced in November 2001, Socket 479 was designed for use in laptops and other low-power portable devices. It initially supported mobile Pentium III-M processors, facilitating the transition to thinner, more battery-efficient laptops in the early 2000s. By providing a standardized interface for low-voltage mobile CPUs, Socket 479 enabled manufacturers to build compact systems with improved power management, contributing to the growth of portable computing during a period when mobility demanded balanced performance and energy efficiency. The socket underwent revisions over its lifecycle to accommodate subsequent processor generations, such as the Pentium M series, extending its relevance in mobile platforms.

Design Purpose

Socket 479 was engineered as a dedicated for mobile processors to address the demands of low-power operation and efficient heat dissipation in compact environments. This design choice stemmed from the need to optimize performance within the constraints of battery life and thermal limits inherent to portable , prioritizing reliability and manufacturability for widespread adoption in mobile platforms. Central to its architecture were principles focused on a compact form factor to fit thin-and-light devices, compatibility with Flip-Chip (FCPGA) packaging for enhanced thermal contact, and integration with specialized mobile chipsets like the 855 series to ensure efficient power delivery and system-level performance. These elements allowed for a surface-mount, zero-insertion-force interface that supported robust electrical connectivity while minimizing mechanical stress in mobile assemblies. In contrast to desktop sockets, which accommodated higher-power components, Socket 479 facilitated significant reductions in power consumption—targeting mobile CPUs operating at 1–2 GHz with thermal design powers ranging from 5 W to 27 W—thereby simplifying thermal management through integrated heat spreaders and smaller cooling solutions suited to space-limited . This approach not only extended battery runtime but also reduced overall system heat output, making it ideal for sustained mobile use without the bulkier cooling requirements of desktop-oriented designs.

History

Initial Development

Intel initiated the development of Socket 479, also known as mPGA479M, in 2001 to support its evolving lineup of mobile processors based on the Pentium III architecture. This socket was designed specifically for the Micro-FCPGA package format, accommodating up to 479 pins and targeting low-power mobile applications. The initial specification, outlined in Intel Application Note 298520-001, provided detailed mechanical, electrical, and reliability guidelines for manufacturing robust, high-volume sockets compatible with these processors. Socket 479 was introduced in November 2001, following the July 2001 release of the Tualatin-core Mobile -M processors, which marked a significant advancement in performance and efficiency. These processors, operating at clock speeds from 866 MHz to 1.333 GHz, utilized the new socket to enable better integration in notebook designs compared to prior mobile formats. The socket's introduction facilitated the transition from earlier packaging like PPGA and BGA used in previous mobile variants. To ensure seamless adoption, collaborated closely with manufacturers and developers for integration into mobile platforms, notably the Intel 830MP chipset released concurrently in July 2001. This partnership involved joint testing and validation, including the use of Intel test vehicles and supplier fixtures from partners like Nanya Technology, to verify socket reliability under mobile operating conditions. The 830MP , supporting AGTL+ signaling and up to 1 GB of PC133 SDRAM, was pivotal in enabling early Socket 479-based systems from OEMs such as for their series launched later that year.

Adoption and Revisions

Socket 479 experienced rapid adoption in 2003 alongside the launch of Intel's Banias-core processors, which were designed for as part of the platform. This integration marked a shift toward power-efficient architectures in laptops, with manufacturers like and incorporating the socket into mid-range models such as the Dell Latitude D series and IBM ThinkPad T series to deliver enhanced battery life and performance compared to prior mobile variants. The Socket 479 supported higher clock speeds up to 2.26 GHz and memory via compatible chipsets like the 855 series, enabling broader compatibility with evolving mobile workloads. In 2004, the socket accommodated the Dothan-core processors, which featured a , 2 MB L2 cache, and 533 MT/s , extending its utility without major physical redesigns. By the second quarter of 2004, processors compatible with Socket 479, particularly the series, achieved approximately 31.8% market share in the U.S. notebook segment, reflecting strong penetration in mid-range laptops. The socket's lifecycle extended through 2006, supporting M derivatives and remaining a staple in mobile platforms until the transition to Socket M for Core microarchitecture-based CPUs.

Technical Specifications

Physical Design

The Socket 479, also known as the mPGA479M, features a compact socket body measuring approximately 35 mm by 35 mm to accommodate the Micro Flip-Chip (Micro-FCPGA) processors designed for mobile applications. This design includes 479 pin contacts arranged in a 26x26 grid array with a 14x14 center gap, utilizing a 1.27 mm pitch to ensure precise alignment and support for the processor's pin configuration, where one corner pin hole is blocked to prevent incorrect orientation. The overall socket dimensions extend to 35.8–36.2 mm in width and 43–44 mm in length when including the actuation mechanism, with a height of 2.8–3.2 mm beneath the package seating plane post-reflow. A key mechanical feature is its (ZIF) mechanism, which employs a lever-actuated release operated by a 4.0–4.5 mm flathead with a maximum of 0.92 N-m, allowing for straightforward insertion and removal of the CPU without damaging the pins. This ZIF design incorporates retention clips that provide a minimum retention force of 10 lbf to securely hold the processor in place during operation, contributing to the socket's maximum compressive load tolerance of 50 lbf and overall weight of 14 g. The socket is specifically engineered for compatibility with lidless Micro-FCPGA processor modules, which have substrate dimensions of 34.9–35.1 mm square and an overall height from the top of the die to the seating plane ranging from 1.88–2.02 mm. To prevent misinsertion, it includes alignment keys such as a triangular feature and standoff at the A1 corner, along with no through-hole at that position, ensuring proper orientation of the processor's 478 pins (each 1.95–2.11 mm long). These structural elements support in mobile systems by facilitating close integration with heatsinks.

Electrical and Mechanical Features

Socket 479 employs a core voltage range of 0.8 to 1.5 V, paired with AGTL+ signaling on the to support processor frequencies up to 2.6 GHz while maintaining low power consumption suitable for mobile platforms. This signaling technology, a low-voltage variant of Gunning Transceiver Logic, ensures efficient data transfer with a termination voltage of 1.05 V nominal for bus signals. The (TDP) ranges from 5 W to 34 W, optimizing for battery life and thermal management in laptops without requiring beyond passive heatsinks. The socket's 479-pin configuration includes pins dedicated to address, data, control functions for the processor's interface with the and , as well as power and ground distribution to provide stable voltage delivery and reduce noise. Reserved pins support thermal monitoring, notably the DI_DTS (Digital Thermal Sensor) pin, which outputs data to enable proactive throttling and prevent overheating during sustained loads. Electrical specifications include a maximum mating resistance of 25 mΩ, inductance below 3.0 nH, and capacitance under 1.0 pF per contact. Mechanically, Socket 479 is engineered for robustness in portable devices, accommodating an range of 0 to 105°C to handle varying environmental conditions. These tolerances, combined with the socket's zero-insertion-force mechanism, enhance reliability in mobile scenarios.

Compatible Processors

Early Mobile Processors

The Socket 479 was introduced alongside the first mobile processors based on Intel's Tualatin core, marking an early step in transitioning to more efficient architectures. The Pentium III-M processors, utilizing the Tualatin core fabricated on a 0.13-micron process, were released in with clock speeds ranging from 800 MHz to 1.2 GHz and featured 512 KB of on-die L2 cache. These processors were designed specifically for mobile applications, offering improved performance over prior Coppermine-based mobile chips while supporting upgrades via the new Socket 479 interface. Following the Pentium III-M, introduced Mobile variants derived from the Tualatin core in 2002, targeting budget-oriented mobile systems with clock speeds from 1.0 GHz to 1.3 GHz and 256 KB of L2 cache. These processors maintained compatibility with Socket 479, providing a cost-effective entry point for without the full feature set of the Pentium III-M lineup. Key features of these early Socket 479 processors included support for a 133 MHz (FSB), which enhanced data throughput compared to earlier 100 MHz designs, and full compatibility with (SSE) instructions for improved processing. Additionally, the Tualatin core incorporated initial power optimizations, such as dynamic voltage scaling and reduced (TDP) ratings between 7 W and 22 W, to extend battery life in portable devices.

Pentium M and Celeron M Series

The processors utilizing the core represented a significant advancement in efficiency when introduced in March 2003, targeting laptops with clock speeds ranging from 900 MHz to 1.7 GHz, a unified 1 MB on-die L2 cache, and a 400 MHz (FSB). These processors incorporated Enhanced technology, enabling dynamic voltage and frequency scaling to optimize power consumption while maintaining performance, with (TDP) typically at 24.5 W for standard models. Designed for the mPGA479M socket, cores emphasized low-power operation through features like deeper sleep states, making them ideal for battery-constrained environments. In 2004, Intel upgraded the Pentium M lineup with the Dothan core, fabricated on a and released starting in May, offering clock speeds up to 2.13 GHz, a doubled 2 MB L2 cache, and support for both 400 MHz and 533 MHz FSB configurations to enhance data throughput. This iteration retained Enhanced SpeedStep for power management but introduced improved branch prediction and larger cache to boost integer and floating-point performance without increasing TDP beyond 27 W in high-end variants. Like its predecessor, Dothan maintained compatibility with Socket 479, enabling seamless upgrades in existing mobile platforms while prioritizing through advanced microarchitectural tweaks. The Celeron M series, positioned as entry-level counterparts to , debuted in January 2004 with the 300 series models based on a stripped-down architecture, featuring clock speeds from 1.0 GHz to 1.5 GHz, a 512 KB L2 cache, and 400 MHz FSB, all within a 24.5 W TDP envelope. By 2005-2006, the 400 series evolved to Dothan derivatives, reaching up to 2.0 GHz with select models offering 1 MB L2 cache for better multitasking in budget laptops, while preserving Enhanced SpeedStep and Socket 479 pinout for broad compatibility. These processors focused on cost-effective performance, omitting advanced features like full instructions in early variants to reduce complexity. In 2005, expanded Socket 479's ecosystem by adapting its C7-M processors—low-power x86 chips with clock speeds from 1.0 GHz to 2.0 GHz, 128 KB L2 cache, and integrated —for compatibility with existing Intel-compatible motherboards, leveraging the socket's physical layout despite a proprietary V4 bus interface. This third-party integration allowed slim notebooks and embedded systems to utilize VIA's 90 nm core designs, which emphasized with TDPs as low as 15 W, providing an alternative to Intel's offerings in niche markets.

Naming and Compatibility Issues

Socket Naming Variations

The official designation for Socket 479, as defined by , is mPGA479M, the Mobile Processor Micro-FCPGA Socket; this terminology appears in Intel's specification document for (ZIF) sockets designed for mobile processors in the Micro-FCPGA package with up to 479 pins, dated November 2001. In marketing materials and general technical literature, the socket is commonly known simply as Socket 479, a that emphasizes its 479-pin configuration while aligning with Intel's broader socket naming conventions for mobile platforms introduced around 2001. Additionally, early documentation and enthusiast discussions informally referred to it as "Mobile Socket 478" due to the actual 478 pins present on compatible processors (with one pin omitted for keying), fostering myths about seamless upgrades from desktop Socket 478 Pentium 4 systems to mobile Pentium M chips despite incompatible pinouts and voltage requirements. Socket 479 exhibits notable physical and electrical incompatibilities with the desktop-focused Socket 478, despite both utilizing a 478-pin configuration. The key differences lie in the socket's keying mechanism and pin assignments, where Socket 479 incorporates mobile-specific power pins and rearranged signal paths optimized for lower power consumption and thermal management in laptop environments. This design prevents direct insertion of desktop Pentium 4 processors into Socket 479 motherboards or vice versa, as the altered pinout could lead to damage from mismatched voltage delivery. Adapters such as the CT-479 enable the use of Socket 479 mobile processors like the in select desktop motherboards by bridging the electrical differences, but this setup is not reversible and requires support for mobile CPU features. Such adaptations highlight the intentional divergence in design to segregate mobile and desktop ecosystems, ensuring stability but limiting cross-platform swaps without hardware modifications. As the direct successor introduced in 2006, Socket M retains the 478-pin mPGA form factor but features a revised pinout to accommodate the microarchitecture's enhanced features, including support for dual-core processing and higher FSB speeds. This rearrangement renders Socket 479 processors electrically incompatible with Socket M sockets, although the physical dimensions allow for potential insertion in some cases, risking short circuits without proper alignment. Upgrade paths for Socket 479-based systems are confined to intra-socket exchanges, allowing swaps between compatible mobile processors like Celeron M and variants without hardware changes, provided the 's FSB and voltage specifications align. Advancing to subsequent sockets like Socket P, introduced in 2007 for further mobile enhancements, necessitates a full replacement owing to ongoing evolutions in pin assignments and power interfaces that preclude drop-in compatibility.

Legacy

Impact on Mobile Computing

Socket 479 played a pivotal role in advancing by powering the platform, launched in March 2003, which integrated the processor, the Intel 855 chipset family for graphics and memory support, and built-in connectivity via the Intel PRO/Wireless network adapters. This combination enabled a shift toward high-performance laptops that maintained portability, offering enhanced wireless capabilities and balanced power efficiency without sacrificing computational power for everyday tasks like office productivity and multimedia playback. The platform's influence extended to substantial improvements in laptop battery life during the 2002-2005 period, with Centrino-enabled systems achieving up to 33% longer runtime—extending from under 3 hours to over 4 hours on a standard 6-cell battery in thin-and-light form factors—through innovations like Enhanced Intel SpeedStep Technology for dynamic voltage and . These gains, coupled with competitive performance in multitasking, helped propel 's dominance in the processor market. Furthermore, Socket 479's design spurred advancements in thermal management and integration, featuring low ratings of 5-27 and the Thermal Monitor for automatic frequency throttling to prevent overheating, which optimized cooling in compact chassis. These elements, including aggressive and power states like Deeper (down to 0.55 consumption), laid foundational concepts for efficient mobile architectures that later influenced the development of ultrabooks by prioritizing sustained in battery-constrained environments.

Discontinuation and Successors

Socket 479 reached the end of its primary support lifecycle in 2006, with the final compatible processors being the Dothan-core series, which represented 's last single-core mobile offerings on this socket before the shift to dual-core architectures. formally discontinued the official specifications for Socket 479 in 2007 as part of the broader transition to the Core , prioritizing enhanced performance and power efficiency in newer platforms. The direct successor to Socket 479 was Socket M, introduced in early 2006 to accommodate the Duo and Core Solo processors, featuring a revised pinout with a 478-pin count and similar mechanical footprint to Socket 479 (479 pins) for potential upgrade compatibility in some systems, but with electrical incompatibility. This was followed by Socket P in May 2007, designed for the Santa Rosa platform, which introduced improved power delivery capabilities, a MHz , and support for DDR2-667 memory to meet the demands of more advanced mobile Core 2 Duo processors. Despite the official phase-out, Socket 479 maintained a niche aftermarket presence in refurbished laptops through approximately 2010, where older systems were upgraded or repurposed for budget computing needs. Additionally, produced rare adaptations with its C7-M processors compatible with Socket 479 chipsets like the VN800, offering an alternative x86 option for low-power mobile applications during the socket's twilight years.

References

  1. https://download.intel.com/design/mobile/applnots/29852001.pdf
  2. https://www.cpu-world.com/Sockets/Socket%20479%20(mPGA479M).html
  3. https://download.intel.com/design/intarch/designgd/30066905.pdf
  4. https://theretroweb.com/misc/documentation/29852001-65c7f08d6fea3112640535.pdf
  5. http://www.datasheet.hk/download.php?id=1611979&pdfid=5171F75E474600939413136E66EC16BC&file=0307%255C82830mp_1036627.pdf
  6. https://theretroweb.com/chipsets/308
  7. https://arstechnica.com/features/2004/02/pentium-m/
  8. https://www.cnet.com/tech/tech-industry/laptop-makers-mobilize-pentium-m-models/
  9. https://scispace.com/pdf/upstream-innovation-and-product-variety-in-the-u-s-home-pc-3dhjq3ri0a.pdf
  10. https://www.versalogic.com/wp-content/themes/vsl-new/assets/resources/support/pdf/Pentium_M_Datatsheet.pdf
  11. https://www.intel.com/content/dam/www/public/us/en/documents/datasheets/celeron-m-processor-datasheet.pdf
  12. https://download.intel.com/design/network/papers/30117401.pdf
  13. https://www.cpu-world.com/Sockets/Socket%20479%20%28mPGA479M%29.html
  14. https://www.intel.com/pressroom/archive/releases/2001/20010730comp.htm
  15. https://www.cpu-world.com/CPUs/Celeron/TYPE-Mobile%20Celeron%20%28Tualatin%29.html
  16. https://www.techpowerup.com/cpu-specs/pentium-m-1-60.c159
  17. https://www.intel.com/content/www/us/en/content-details/841542/intel-pentium-m-processor-datasheet.html
  18. https://www.techpowerup.com/cpu-specs/pentium-m-765.c153
  19. https://www.mouser.com/datasheet/2/612/30218908-263252.pdf
  20. https://www.cpu-world.com/CPUs/C7-M/index.html
  21. https://www.overclock.net/threads/laptop-socket-479-upgrade.646787/
  22. https://forums.anandtech.com/threads/what-is-the-difference-betwen-intel-socket-479-478.1899281/
  23. https://www.techpowerup.com/forums/threads/socket-479-to-478-adapter.2406/
  24. https://forums.anandtech.com/threads/socket-479-backwards-compatible-to-478.1843218/
  25. https://forums.anandtech.com/threads/socket-479-socket-p.333153/
  26. https://www.intel.com/pressroom/archive/releases/2004/20040510comp.htm
  27. https://www.cpu-world.com/CPUs/Pentium_M/index.html
  28. https://www.ece.ucdavis.edu/~vojin/CLASSES/EEC280/protected/islped04/keynotes/TThakkar-ISPLED04Keynote.pdf
  29. https://www.techpowerup.com/cpu-specs/?f=codename_=Dothan
  30. https://www.cpu-world.com/Sockets/Socket%20M%20%28mPGA478MT%29.html
  31. https://www.intel.com/content/www/us/en/processors/core2/extreme-mobile-processor.html
  32. https://www.theregister.com/2006/06/16/via_socket-479_cpu/
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