Celeron
Celeron is a brand of low-cost x86 microprocessors developed and manufactured by Intel Corporation, designed primarily for entry-level computing tasks such as web browsing, word processing, email, and light multimedia consumption.[1] Introduced on April 15, 1998, as a budget-friendly variant of the Pentium II processor, Celeron targeted the growing market for inexpensive personal computers, offering reduced features like smaller cache sizes compared to higher-end Intel lines while maintaining compatibility with mainstream x86 software.[2] By the end of 1998, it had become the second-highest volume PC microprocessor worldwide, only behind the original Pentium II, underscoring its rapid adoption in value-oriented systems.[2] Over the years, the Celeron lineup has evolved alongside Intel's architectural advancements, migrating from P6-based designs (Pentium II and III) to NetBurst (Pentium 4), and later to Core microarchitectures, including iterations like Alder Lake (up to 2022).[1] These processors typically feature 2 to 5 cores, base clock speeds from 1.00 GHz to 3.60 GHz, cache sizes of 1 MB to 8 MB, and thermal design power (TDP) ratings between 4 W and 58 W, making them suitable for low-power devices such as netbooks, Chromebooks, and basic desktops or laptops.[1] Key benefits include energy efficiency, reduced heat output, and extended battery life in portable systems, appealing to students, casual users, and small businesses seeking affordable reliability without demanding high performance.[3] The Celeron brand was retired by Intel in 2023, with production of new models ceasing and entry-level processors rebranded as Intel Processor; legacy support extends until 2026 for select variants, such as certain Coffee Lake G-series models.[4][5]Background
Brand Introduction and Purpose
The Celeron brand was launched by Intel on April 15, 1998, as a low-cost derivative of the Pentium II processor, targeting the burgeoning market for affordable personal computers.[6] Designed to deliver essential computing capabilities at a reduced price point, the initial Celeron processor operated at 266 MHz and was positioned for entry-level systems used in homes and small businesses.[6] Its primary purpose was to enable basic tasks such as word processing, web browsing, email, and light multimedia playback, making computing accessible to budget-conscious consumers and emerging markets where cost was a primary barrier.[2] By offering compatibility with existing Pentium II infrastructure while undercutting prices—starting at around $155 per unit in volume—the Celeron aimed to drive widespread adoption of Intel's x86 architecture in value-oriented PCs.[6] Central to the Celeron brand's philosophy was cost reduction through modifications to the parent Pentium II architecture, including lower clock speeds, elimination of secondary (L2) cache in the first generation (known as Covington), and disabling of certain advanced features to avoid the expense of a full redesign.[7] This approach allowed Intel to produce chips on the same 0.25-micron process while targeting systems with simpler motherboards, such as those using the Intel 440EX chipset supporting up to 256 MB of memory.[6] The strategy emphasized reliability and broad compatibility over peak performance, ensuring the processors met the needs of everyday applications without the premium features of higher-end lines like Pentium.[2] Upon release, the Celeron faced criticism for its performance shortcomings, particularly the absence of L2 cache, which created a noticeable gap compared to the full Pentium II and even some older Pentium models.[8] Despite this, the brand achieved commercial success by year's end, becoming the second-highest volume PC microprocessor worldwide—thanks to aggressive pricing and strong demand for economical computing solutions.[2] This volume-driven approach solidified Celeron's role as Intel's entry-level offering, paving the way for its evolution across subsequent generations.Historical Development and Key Milestones
The Intel Celeron brand debuted in 1998 as an entry-level processor line derived from the P6 microarchitecture, initially with the Covington core using Socket 370 packaging.[9] This was followed swiftly by the Mendocino core in August 1998, which introduced groundbreaking on-die 128 KB L2 cache running at full core speed, a significant innovation that improved performance over prior cacheless designs and enabled overclocking popularity.[10] By 2000, Mendocino variants reached speeds up to 533 MHz, solidifying Celeron's position in budget systems.[11] The transition to the NetBurst microarchitecture began in 2001 with the Willamette-based Celeron, shifting to Socket 478 for compatibility with Pentium 4 platforms and incorporating SSE2 instructions for enhanced multimedia support. From 2002 to 2005, Celeron evolved within the NetBurst family, with Northwood cores at 130 nm refining power efficiency and clock speeds up to 2.8 GHz. The introduction of the Celeron D series in 2004 marked a key adaptation, using 90 nm Prescott cores to reduce costs while supporting higher front-side bus speeds of 533 MHz in select models. Some later Celeron D variants, like the 3xx J series in 2005, incorporated Hyper-Threading Technology for modest multithreading gains in single-core designs, aligning with broader Intel efforts to boost entry-level multitasking.[12] A pivotal shift occurred in 2006 with the adoption of the Core microarchitecture in the Conroe-L core, launching the Celeron 400 series at 65 nm on Socket 775; this ended the NetBurst era, delivering superior instructions per clock and power efficiency over predecessors, with single-core models starting at 1.6 GHz and 512 KB L2 cache.[13] By 2008–2011, Celeron integrated further advancements, including the Clarkdale core in 2010 based on Westmere at 32 nm, which pioneered on-package dual-core designs with integrated Intel HD Graphics for the first time in the lineup, enhancing value in all-in-one and media PCs via LGA 1156 socket. From 2011 to 2022, Celeron closely mirrored mainstream Core generations for cost-effective scaling, incorporating architectures like Sandy Bridge (2011) for integrated graphics improvements, Ivy Bridge (2012) at 22 nm, and successive shrinks through Haswell, Broadwell, Skylake, and beyond, often with dual-core configurations and up to 2 MB cache. This period emphasized alignment with Intel's 14 nm process nodes starting in 2015, enabling features like DDR4 support and low-power optimizations for embedded and basic computing. The 2022 Alder Lake generation represented the final major milestone for branded Celeron, introducing hybrid performance (P-cores) and efficiency (E-cores) overall, though low-end models like the G6900 used only 2 P-cores in a dual-core 46 W configuration on LGA 1700 supporting DDR5 and PCIe 5.0, before the brand's phase-out announced in 2022 and effective from Q1 2023 for consumer products in favor of unified Intel Processor labeling.[14]Desktop Celerons
P6 and NetBurst-based Models
The early desktop Celeron processors based on the P6 microarchitecture were introduced as budget alternatives to the Pentium II and Pentium III, featuring reduced cache sizes to lower costs while supporting mainstream desktop applications like office productivity and basic internet use. Launched in 1998, the Covington core was essentially a Pentium II without off-die L2 cache, using a 0.25 μm process, with clock speeds of 266–300 MHz and a 66 MHz front-side bus (FSB), packaged in Slot 1 for compatibility with existing motherboards but requiring higher voltages that increased power draw to around 17 W.[15] The Mendocino core, introduced later in 1998, marked the first on-die L2 cache for Celerons at 256 KB running at full core speed, shifting to a 0.18 μm process and Socket 370 packaging, with speeds from 466 MHz to 1.1 GHz and TDP around 14–20 W. This design improved performance over Covington by 20–30% in cache-sensitive tasks due to the integrated cache, though it still lacked features like SSE instructions in early models.[16] Subsequent P6-based generations included the Coppermine-128 core in 1999, which added SSE support and 128 KB on-die L2 cache on 0.18 μm, reaching up to 1.1 GHz on Socket 370, and the Tualatin core in 2001 on 0.13 μm with 256 KB L2, clock speeds up to 1.4 GHz, and improved power efficiency at 25–35 W TDP, supporting 100/133 MHz FSB for better memory bandwidth in value desktops.[17][18] These processors emphasized affordability for home and small office PCs, with Socket 370 enabling compact, low-cost systems.| Model | Introduction Year | Process Node | L2 Cache | Clock Speed Range | TDP | Key Features |
|---|---|---|---|---|---|---|
| Covington | 1998 | 0.25 μm | None | 266–300 MHz | ~17 W | Slot 1; no L2 cache for cost reduction |
| Mendocino | 1998 | 0.18 μm | 256 KB | 466 MHz–1.1 GHz | 14–20 W | On-die L2; Socket 370 |
| Coppermine-128 | 1999 | 0.18 μm | 128 KB | 500 MHz–1.1 GHz | ~20 W | SSE support; improved branch prediction |
| Tualatin | 2001 | 0.13 μm | 256 KB | 1.0–1.4 GHz | 25–35 W | 133 MHz FSB; better efficiency |
Core Microarchitecture-based Models (2006–2011)
The introduction of Core microarchitecture-based Celeron processors in 2006 represented a pivotal evolution for Intel's entry-level desktop lineup, shifting from the power-hungry NetBurst architecture to a more efficient, multi-core design optimized for everyday computing tasks. These processors, fabricated on 65 nm and later process nodes, emphasized improved instructions per clock (IPC) and lower power consumption, enabling better performance in budget systems without the need for discrete graphics in later models. This era introduced dual-core capabilities to Celerons, addressing the growing demand for parallel processing in applications like web browsing and office productivity, while maintaining compatibility with Socket 775 and later LGA 1156 platforms. The initial models, known as Conroe-L and Allendale, launched in 2006–2007 and were derived from the Conroe core, featuring 65 nm fabrication and a front-side bus (FSB) of 800 MT/s. Conroe-L variants, such as the Celeron 420 (1.6 GHz, single core, 512 KB L2 cache, 27 W TDP), targeted cost-sensitive users by halving the cache of mainstream Core 2 Duo processors while retaining the wide execution engine for enhanced IPC over prior generations.[23] Allendale-based dual-core models, like the Celeron E1200 (1.6 GHz, 2 cores, 512 KB L2 cache, 65 W TDP), extended this efficiency to multi-threaded workloads, offering up to 40% better performance than equivalent NetBurst Celeron D processors at similar clock speeds due to the Core's superior branch prediction and out-of-order execution.[24] These chips supported DDR2 memory and lacked features like Intel 64 in early single-core versions, but later revisions added it for broader OS compatibility. In 2008, Intel transitioned to the 45 nm Wolfdale-3M core with models such as the Celeron E3200 (2.4 GHz, 2 cores, 1 MB L2 cache, 65 W TDP), marking the first process shrink for Celeron and yielding approximately 15–20% gains in performance per watt over 65 nm predecessors through reduced leakage and improved transistor density.[25] This generation doubled the L2 cache compared to Allendale, enhancing hit rates for common desktop applications, while retaining Socket 775 compatibility and FSB at 800 MT/s. The Wolfdale Celerons, including higher-speed options like the E3500 (2.7 GHz), provided a balanced upgrade path for older systems, with power efficiency improvements enabling quieter, cooler operation in value-oriented desktops. The 2010 Clarkdale processors introduced integrated graphics to desktop Celerons, debuting with the Celeron G1101 (2.26 GHz, 2 cores, 2 MB shared L3 cache, 73 W TDP, 32 nm CPU process), paired with Intel HD Graphics (Ironlake, 45 nm GPU) on a single die connected via QuickPath Interconnect.[26] This 32 nm shrink further boosted efficiency, supporting DDR3 memory on LGA 1156 and offering up to 50% better performance per watt than NetBurst-era Celerons through architectural refinements like wider decode units and better power gating.[27] The integrated GPU handled basic display and light media tasks, reducing system costs by eliminating discrete cards for many users. For embedded applications, low-power variants like those based on Jasper Forest (Nehalem, 45 nm) existed, such as the single-core Celeron 210 (1.2 GHz, 512 KB L2, 31 W TDP, with integrated graphics), but mainstream desktop focused on Clarkdale.[28] Overall, these Core-based Celerons delivered seminal advancements in multi-core entry-level computing, with the 45 nm transition in Wolfdale and integrated graphics in Clarkdale paving the way for more versatile, energy-efficient budget processors that achieved up to 4x better performance per watt in some workloads compared to NetBurst designs.[27]Nehalem and Westmere-based Models (2009–2011)
Desktop Celeron processors based on the Nehalem microarchitecture were limited to embedded variants like Jasper Forest (45 nm), with no mainstream desktop releases; the first integrated desktop Celerons arrived with the Westmere-based Clarkdale in 2010.[29] The Celeron G1101 (codename Clarkdale) featured two cores and two threads at 2.26 GHz, 2 MB shared L3 cache, and 73 W TDP.[30] It used LGA 1156 and included an integrated memory controller supporting dual-channel DDR3-1066 up to 8 GB.[30] The Direct Media Interface (DMI) at 2.5 GT/s improved system interconnects.[26] The 32 nm Westmere process reduced power leakage compared to Nehalem's 45 nm, aiding compact desktops. It integrated first-generation Intel HD Graphics at 533 MHz, supporting DirectX 10 and video decode, but omitted AES-NI and Hyper-Threading for cost savings.[30] With 382 million transistors, it suited small form-factor PCs.[26] These targeted basic tasks, with PassMark scores around 1,000 single-threaded.[31] Launched at $85 MSRP in January 2010, it bridged to Sandy Bridge.[26]Sandy Bridge to Coffee Lake-based Models (2011–2018)
The Sandy Bridge-based Celeron processors, introduced in 2011, marked a significant evolution for Intel's entry-level desktop lineup by adopting the 32 nm process node and integrating advanced features like the ring bus interconnect for improved cache access. These dual-core models, such as the Celeron G530 operating at 2.4 GHz with 2 MB of L3 cache and a 65 W TDP, utilized the LGA 1155 socket and included Intel HD Graphics with 6 execution units, enabling basic hardware-accelerated video decoding via Quick Sync Video.[32] This generation built on the integrated memory controller legacy from Nehalem architectures, supporting DDR3 memory up to 1333 MT/s. With the Ivy Bridge refresh in 2012, Celeron processors shifted to the 22 nm tri-gate process for better power efficiency while maintaining dual-core configurations and the LGA 1155 socket. Representative models like the G1610 ran at 2.6 GHz with 2 MB L3 cache and a 55 W TDP, featuring upgraded Intel HD Graphics 2500 with the same 6 execution units but improved shaders for modest gains in 3D performance and video encoding.[33] The Haswell generation in 2013 retained the 22 nm node but introduced optimizations like improved branch prediction and AVX2 instructions, with desktop Celerons such as the G1840 at 2.8 GHz, 2 MB L3 cache, 53 W TDP, and LGA 1150 socket, paired with Intel HD Graphics (Haswell) offering 10 execution units for enhanced media playback capabilities.[34] No Broadwell-based desktop Celeron processors were released in 2015; Intel focused on mobile and embedded variants using the 14 nm process. The Skylake architecture in 2015 brought the 14 nm process to mainstream desktop Celerons, exemplified by the G3900 at 2.8 GHz, 2 MB L3 cache, 51 W TDP, and LGA 1151 socket, incorporating Intel HD Graphics 510 with 12 execution units for better DirectX 12 support and 4K video decode. Kaby Lake in 2017 served as an optimized 14 nm+ refresh, with models like the G3930 at 2.9 GHz, retaining 2 MB L3 cache and 51 W TDP, but upgrading to Intel HD Graphics 610 for refined media processing and efficiency.[35] The Coffee Lake generation in 2018 further refined the 14 nm++ process, introducing models such as the G4900 at 3.1 GHz with 2 MB L3 cache, 54 W TDP, and LGA 1151 socket (v2), featuring Intel UHD Graphics 610 with 12 execution units capable of native 4K output and HEVC 10-bit decoding.[36] Throughout this era, core counts remained at two without hyper-threading, emphasizing cost-effective designs for basic computing, while integrated graphics progressed from rudimentary HD variants to UHD capabilities supporting modern display standards.| Generation | Process Node | Representative Model | Cores/Threads | L3 Cache | TDP | Integrated Graphics | Socket |
|---|---|---|---|---|---|---|---|
| Sandy Bridge (2011) | 32 nm | G530 | 2/2 | 2 MB | 65 W | HD Graphics (6 EUs) | LGA 1155 |
| Ivy Bridge (2012) | 22 nm | G1610 | 2/2 | 2 MB | 55 W | HD 2500 (6 EUs) | LGA 1155 |
| Haswell (2013) | 22 nm | G1840 | 2/2 | 2 MB | 53 W | HD Graphics (10 EUs) | LGA 1150 |
| Skylake (2015) | 14 nm | G3900 | 2/2 | 2 MB | 51 W | HD 510 (12 EUs) | LGA 1151 |
| Kaby Lake (2017) | 14 nm+ | G3930 | 2/2 | 2 MB | 51 W | HD 610 (12 EUs) | LGA 1151 |
| Coffee Lake (2018) | 14 nm++ | G4900 | 2/2 | 2 MB | 54 W | UHD 610 (12 EUs) | LGA 1151 v2 |
Comet Lake to Alder Lake-based Models (2019–2022)
The Comet Lake-based Celeron processors, introduced in 2019 as part of Intel's 10th-generation desktop lineup, represented a continuation of the budget-oriented architecture from prior generations while supporting the new LGA 1200 socket and 400-series chipsets. These models featured dual-core configurations without hyper-threading, built on a refined 14nm process, with integrated Intel UHD Graphics 610 for basic display output. Representative examples include the Celeron G5900, operating at a base frequency of 3.40 GHz with 2 MB of L3 cache and a 58 W TDP, and the G5905, which boosts cache to 4 MB while maintaining similar clock speeds and power envelope.[38][39] These processors targeted entry-level systems for everyday computing, emphasizing affordability over performance enhancements like turbo boosting, which were absent in the Celeron lineup. In 2021, with the launch of 11th-generation Rocket Lake processors, Intel did not introduce new Celeron silicon for desktops but instead refreshed Comet Lake-based models for compatibility with 500-series chipsets, enabling PCIe 4.0 support for improved peripheral connectivity. This refresh maintained the dual-core design, 14nm fabrication, and UHD Graphics 610, with no architectural changes to core counts or cache sizes. For instance, the Celeron G5920, a refreshed variant, delivered a 3.50 GHz base frequency, 2 MB L3 cache, and 58 W TDP, suitable for budget builds requiring modern I/O without overclocking capabilities.[40][41] These updates focused on platform longevity rather than performance uplifts, bridging the gap to next-generation architectures while keeping costs low for basic office and media tasks. The transition to Alder Lake in 2022 marked the final evolution of desktop Celerons, adopting Intel's hybrid core architecture on the Intel 7 process (equivalent to 10nm) and LGA 1700 socket, with support for both DDR4 and DDR5 memory. Low-end models like the Celeron G6900 eschewed efficiency cores, relying solely on two performance cores (P-cores) at 3.40 GHz base frequency, 4 MB L3 cache (plus 2.5 MB L2), and a 46 W TDP, paired with Intel UHD Graphics 710 for enhanced video decode capabilities.[42] Released in January 2022 as the last Celeron desktop offering, the G6900 exemplified the brand's shift toward enabling PCIe 4.0 lanes and future-proofing for entry-level systems, though it retained non-overclockable locked multipliers and prioritized power efficiency over multi-threaded workloads.[43] This generation underscored Celeron's role in sustaining affordable computing amid Intel's broader pivot to hybrid designs, before the brand's eventual phase-out.Mobile Celerons
P6 and NetBurst-based Models
The early mobile Celeron processors based on the P6 microarchitecture were designed for entry-level laptops, prioritizing low power consumption and extended battery life over high performance, making them suitable for tasks like document editing, email, and light multimedia. Introduced in 1999, the Mendocino core represented Intel's first on-die L2 cache implementation in a budget mobile CPU, using a 0.18 μm manufacturing process to integrate 256 KB of full-speed L2 cache, with clock speeds reaching up to 1 GHz and a thermal design power (TDP) of 14 W. These processors supported basic mobile computing needs while consuming significantly less power than contemporary desktop equivalents, thanks to mobile-optimized voltage regulation that reduced average power draw during idle states. Building on the Mendocino foundation, the Tualatin-256 core arrived in 2001, refined on a 0.13 μm process for improved efficiency, retaining 256 KB L2 cache but adding Enhanced Intel SpeedStep Technology for dynamic frequency and voltage scaling—allowing the CPU to drop to lower speeds under light loads to conserve battery life. Clock speeds extended up to 1.3 GHz, with TDPs varying from 7 W in low-power variants to 24 W in higher-speed models, enabling better thermal management in slim laptops.[44] This generation emphasized power efficiency for portables, with integrated features like pause states that further minimized energy use during inactivity, positioning it as a cost-effective choice for business and educational mobile devices.[45]| Model | Introduction Year | Process Node | L2 Cache | Clock Speed Range | TDP | Key Features |
|---|---|---|---|---|---|---|
| Mendocino | 1999 | 0.18 μm | 256 KB | 266 MHz – 1 GHz | 14 W | On-die L2 cache; mobile voltage scaling for battery optimization |
| Tualatin-256 | 2001 | 0.13 μm | 256 KB | 650 MHz – 1.3 GHz | 7–24 W | Enhanced SpeedStep; improved power gating for idle efficiency |
Pentium M and Core-based Models (2004–2008)
The transition to Core microarchitecture-based mobile Celerons began with derivatives of the Pentium M, emphasizing low-power consumption for ultraportable laptops. The Shelton series, introduced in January 2004, served as an entry-level variant of the Banias-core Pentium M, featuring a single core with 512 KB L2 cache on a 90 nm process and thermal design power (TDP) options from 5 W for ultra-low-voltage (ULV) models to 21 W for standard variants.[49] These processors integrated Enhanced SpeedStep technology for dynamic power management, enabling longer battery life in thin-and-light notebooks.[50] Following Shelton, the Dothan-based Celeron M processors extended the lineup in mid-2004, retaining the single-core design with 512 KB L2 cache but shifting to a 90 nm process for improved efficiency over Banias, with TDP similarly ranging from 5 W ULV to 21 W.[50] This generation supported the Intel Centrino platform, combining the CPU with integrated Wi-Fi and chipset for certified mobile performance and power savings.[49] In 2006, Intel launched the Celeron M 400 series based on the Yonah core, marking the shift to 65 nm process technology and introducing single-core models with 1 MB L2 cache and TDP of 27 W for standard versions or as low as 5.5 W for ULV configurations.[51] Optimized for Centrino Duo platforms, these processors enhanced multi-threaded efficiency for basic mobile tasks while prioritizing low power for extended portability.[52] The Merom-based Celeron M 500 series arrived in 2007, offering single-core Merom-L variants with 1 MB L2 cache and ultra-low TDP of 5.5 W on 65 nm, alongside dual-core Merom-2M options with 1 MB shared L2 cache at 31 W TDP.[51] These models supported Intel 64 and SSSE3 instructions, integrating seamlessly with Centrino for netbook and ultraportable applications focused on web browsing and light productivity.[52] By 2008, the Penryn-3M core underpinned the Celeron 900 series, featuring dual cores with 1 MB shared L2 cache on a 45 nm process, TDP from 5.5 W ULV to 31 W, and the addition of SSE4.1 for improved media processing.[53] Designed for Centrino 2 platforms, this lineup delivered sub-10 W power envelopes in select variants, enabling fanless designs in early netbooks and emphasizing battery life up to 8 hours in low-power scenarios.[53]| Model Series | Core | Cores | L2 Cache | Process | TDP Range (W) | Key Platform |
|---|---|---|---|---|---|---|
| Shelton (2004) | Banias/Dothan | 1 | 512 KB | 90 nm | 5–21 | Centrino |
| Yonah (2006) | Yonah | 1 | 1 MB | 65 nm | 5.5–27 | Centrino Duo |
| Merom (2007) | Merom-L/2M | 1–2 | 1 MB | 65 nm | 5.5–31 | Centrino |
| Penryn (2008) | Penryn-3M | 2 | 1 MB | 45 nm | 5.5–31 | Centrino 2 |
Nehalem to Ivy Bridge-based Models (2009–2013)
The Nehalem and Westmere microarchitectures laid the foundation for mobile Celerons in this era, with Arrandale representing the first integration of graphics processing units (GPUs) directly onto the processor die, enabling more efficient laptop designs without relying on discrete graphics cards. Released in 2010, Arrandale-based mobile Celerons, such as the P4500 and U3400 models, featured dual cores operating at clock speeds around 1.2 to 1.86 GHz, with 2 MB of shared L3 cache, fabricated on a 32 nm process. These processors supported dual-channel DDR3 memory up to 1066 MHz and included Intel HD Graphics running at base frequencies of 166–500 MHz, marking a shift toward unified system-on-chip architectures for entry-level ultraportables and netbooks.[54] Thermal design power (TDP) ranged from 18 W for ultra-low-voltage (ULV) variants like the U3400 to 35 W for higher-performance options, using the BGA1288 package to facilitate compact laptop integration.[55] Building on this, the 2011 Sandy Bridge mobile Celerons refined the design for better efficiency, introducing models like the 857 with dual cores at 1.2 GHz, 2 MB L3 cache, and the same 32 nm process node. These chips paired Intel HD Graphics 2000, capable of handling basic 1080p video playback, with continued DDR3 support up to 1333 MHz, while maintaining a low 17 W TDP to prioritize portability in budget thin-and-light laptops.[55] Platforms based on Sandy Bridge began incorporating USB 3.0 support through compatible chipsets like the HM77, allowing faster data transfers for external storage and peripherals without additional hardware.[56] The 2012 Ivy Bridge lineup advanced mobile Celerons further with a 22 nm tri-gate process, enhancing power efficiency and enabling longer battery life in ultrabooks and tablets compared to prior 32 nm designs.[57] Representative models included the 1005M at 1.9 GHz and the ULV 1007U at 1.5 GHz, both with dual cores and 2 MB L3 cache, integrating Intel HD Graphics 4000 for improved rendering of web content and light gaming. These processors retained DDR3 compatibility up to 1600 MHz and a 17 W TDP for ULV variants, contributing to up to 20% better battery endurance in typical mobile workloads through reduced leakage current and optimized voltage scaling.[58] Overall, this generation solidified Celerons as viable for affordable, graphics-capable mobile computing, emphasizing integrated features over raw performance.Haswell to Kaby Lake-based Models (2013–2017)
The Haswell-based mobile Celeron processors, introduced in 2013, marked a significant advancement in low-power computing for entry-level laptops and ultrabooks, featuring dual-core architectures without hyper-threading. These processors, such as the Celeron 2955U and 2957U, operated on Intel's 22nm process with 2MB of L3 cache and integrated Intel HD Graphics (Haswell), supporting up to 10-15W TDP in ultra-low voltage (ULT) configurations for improved battery life in thin-and-light devices. They enabled basic multitasking and 4K video decode capabilities, a step up from prior generations, while maintaining affordability for budget-conscious consumers. Broadwell mobile Celerons, launched in 2015, were less common in the lineup but refined the architecture on a 14nm process for better power efficiency, retaining the dual-core design with 2MB cache. Models like the Celeron 3205U featured Intel HD Graphics 5500, which offered marginal improvements in integrated graphics performance over Haswell, though Celeron variants were rare compared to Pentium or Core offerings in this generation. These processors targeted similar 10-15W TDP envelopes, emphasizing thermal management for fanless designs in tablets and convertibles. Kaby Lake mobile Celerons in the U-series, introduced in 2017, built on the 14nm+ process for minor clock speed uplifts and efficiency gains, sticking to dual cores and 2MB cache in models like the Celeron 3965U, paired with Intel HD Graphics 505. These supported Intel Optane Memory for storage acceleration, enhancing perceived performance in entry-level systems without increasing TDP, which remained at 6-15W. The architecture prioritized compatibility with emerging 2-in-1 form factors, delivering reliable 4K video support and basic web browsing in power-constrained environments. Parallel N-series Celerons on Gemini Lake (Goldmont Plus cores), such as the N4000 series, offered quad cores with 4 MB cache and 6 W TDP for low-power applications. Skylake mobile Celerons in the U-series, released later in 2015, continued the dual-core, 2MB cache configuration on the 14nm process, with models such as the Celeron 3855U supporting Intel HD Graphics 510 for enhanced video playback and light media tasks. TDP options ranged from 6W to 15W, enabling deployment in ultra-portable 2-in-1 convertibles and Chromebooks with improved instruction sets like AVX2 for basic productivity applications. The generation focused on balancing cost and efficiency, with integrated graphics capable of 4K output at lower power draws. Parallel N-series Celerons on Braswell (Airmont cores), such as the N3000, also launched around 2016 with quad cores and 6 W TDP for ultra-low power devices. Overall, the period from Haswell to Kaby Lake saw mobile Celerons evolve toward greater integration in hybrid devices like 2-in-1 convertibles, with TDP reductions to 6W facilitating longer battery life and silent operation, while process shrinks from 22nm to 14nm+ improved energy efficiency without altering the core entry-level positioning.Coffee Lake to Alder Lake-based Models (2017–2022)
The Coffee Lake-based mobile Celerons, introduced in 2018 as part of Intel's 8th generation processors, represented a continuation of the low-power U-series for entry-level laptops, emphasizing efficiency for basic computing tasks such as web browsing and office productivity. These processors featured dual-core configurations without hyper-threading, built on the 14 nm process, with a 15 W TDP to suit thin-and-light ultrabooks. A representative model, the Intel Celeron 4205U, operated at a base frequency of 1.8 GHz and included 2 MB of L3 cache, paired with Intel UHD Graphics 600 running at 300 MHz base and up to 900 MHz dynamic frequency. Memory support extended to DDR4-2400 and LPDDR4-2400, enabling up to 32 GB, which provided sufficient bandwidth for light multitasking without exceeding power constraints. Transitioning to the 10th generation Comet Lake architecture in 2020, mobile Celerons maintained the 14 nm process but introduced minor refinements in clock speeds and graphics capabilities for improved video playback and casual use. Models like the Celeron 5205U and 5305U were dual-core processors with 2 MB cache and a 15 W TDP (configurable down to 12.5 W), featuring base frequencies of 1.9 GHz and 2.3 GHz, respectively. Integrated Intel UHD Graphics for 10th Generation processors, with a 300 MHz base and 900 MHz max dynamic frequency, supported up to 64 GB of DDR4-2666 or LPDDR4x-2933 memory, enhancing compatibility with emerging 1080p displays. While core counts remained at two for these U-series variants, parallel low-end N-series Celerons (Gemini Lake Refresh) offered up to four cores with 4 MB cache and 6-10 W TDP for fanless designs. The 11th generation Tiger Lake-based Celeron, exemplified by the 2021 Celeron 6305, marked a shift to Intel's 10 nm SuperFin process, delivering better power efficiency and integrated features like an Image Processing Unit (IPU) for enhanced camera processing in video calls. This dual-core, dual-thread processor had a 1.8 GHz base frequency, 4 MB L3 cache, and a 15 W TDP, supporting up to 64 GB of DDR4-3200 or LPDDR4x-3733 memory. Graphics were powered by Intel UHD Graphics at a 350 MHz base frequency, capable of 4K video decode, which improved multimedia handling over prior generations without increasing thermal demands. The architecture's focus on connectivity, including Thunderbolt 4 and Wi-Fi 6 readiness, positioned these chips for modern entry-level devices. By 2022, the Alder Lake generation introduced hybrid core designs to mobile Celerons, blending performance and efficiency cores for balanced workloads in budget laptops. The Celeron 7305, a key example, featured one Golden Cove performance core and four Gracemont efficiency cores for a total of five cores and five threads, with a 1.1 GHz base frequency, 8 MB L3 cache, and 15 W TDP on the Intel 7 process (enhanced 10 nm). It supported DDR5-4800 and LPDDR5-5200 memory up to 64 GB, alongside Intel UHD Graphics for 12th Generation, enabling DDR5's higher bandwidth for smoother everyday performance. The variant Celeron 7305E, launched in the same year, offered similar specs but without the IPU, serving embedded and low-power applications at a 1.0 GHz base. These models were among the final under the Celeron branding, as Intel announced the retirement of the name for mobile processors starting in 2023, consolidating low-end offerings under a unified "Intel Processor" label to simplify market positioning.[4]| Model | Generation | Cores/Threads | Base Freq. (GHz) | Cache (MB) | Process | TDP (W) | Graphics |
|---|---|---|---|---|---|---|---|
| 4205U | Coffee Lake (8th) | 2/2 | 1.8 | 2 | 14 nm | 15 | UHD 600 |
| 5205U | Comet Lake (10th) | 2/2 | 1.9 | 2 | 14 nm | 15 | UHD (10th Gen) |
| 5305U | Comet Lake (10th) | 2/2 | 2.3 | 2 | 14 nm | 15 | UHD (10th Gen) |
| 6305 | Tiger Lake (11th) | 2/2 | 1.8 | 4 | 10 nm SuperFin | 15 | UHD |
| 7305 | Alder Lake (12th) | 5 (1P+4E)/5 | 1.1 | 8 | Intel 7 | 15 | UHD (12th Gen) |
| 7305E | Alder Lake (12th) | 5 (1P+4E)/5 | 1.0 | 8 | Intel 7 | 15 | UHD (12th Gen) |