Qualcomm Snapdragon - Wikipedia

Suite of system-on-a-chip (SoC) semiconductor products Snapdragon

Logo
General information
Launched	November 2007
Marketed by	Qualcomm
Designed by	Qualcomm
Common manufacturer	TSMCSamsung
Architecture and classification
Application	Smartphone Tablet Laptop Smartwatch Embedded system Virtual reality headset Bluetooth audio
Physical specifications
Memory (RAM)	LPDDR SDRAM
GPU	Adreno graphics
Products, models, variants
Core name	Kryo CPUAdreno GPUHexagon DSPSpectra ISPSnapdragon ModemFastConnect WiFi
Model	List of Qualcomm Snapdragon processors
Brand names	Snapdragon X Snapdragon G Snapdragon XR Snapdragon AR Snapdragon 8 Snapdragon 7 Snapdragon 6 Snapdragon 4 Snapdragon 2 Snapdragon W Snapdragon S

Snapdragon is a suite of system-on-chip (SoC) semiconductor products for mobile devices designed and marketed by Qualcomm, who often refers to these SoCs as "mobile platforms". They typically integrate central processing units (CPU) based on the ARM architecture, a graphics processing unit (GPU), some digital signal processors (DSP), and may or may not include a cellular modem. Snapdragon semiconductors are designed for embedded systems, e.g., smartphones, netbooks, and vehicles.[1] In addition to the processors, the lineup also includes modems, Wi-Fi chips and mobile charging products.

The first Snapdragon-branded product was released in December 2007, using CPU based on Qualcomm’s “Scorpion” microarchitecture. The architecture’s successor, “Krait”, was introduced in 2011 and featured asynchronous symmetrical multi-processing: cores can adjust their clock speed and voltage independent to each other.[2] On the announcement of Snapdragon 800 in 2013 Consumer Electronics Show, Qualcomm renamed their prior models to the 200, 400 and 600 series. Qualcomm re-branded its modem products under the Snapdragon name in February 2015.

History

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Pre-release

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Qualcomm announced it was developing the Scorpion central processing unit (CPU) in November 2007.[3][4] The Snapdragon system on chip (SoC) was announced in November 2006 and included the Scorpion processor, as well as other semiconductors.[4][5] This also included Qualcomm's first custom Hexagon digital signal processor (DSP).[6]

According to a Qualcomm spokesperson, it was named Snapdragon, because "Snap and Dragon sounded fast and fierce."[7] The following month, Qualcomm acquired Airgo Networks for an undisclosed amount; it said Airgo's 802.11a/b/g and 802.11n Wi-Fi technology would be integrated with the Snapdragon product suite.[8][9] Early versions of Scorpion had a processor core design similar to the Cortex-A8.[4]

2007-2013: 32-bit ARM

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The first Snapdragon was released in November 2007. CNET noted its relatively high 1 GHz CPU clock speed as the product's "claim to fame", when conpemporary smartphone processors are commonly using 500 MHz CPU.[10][11] The product can output display at up to 720p resolution, render 3D graphics, and supports a up-to 12-megapixel camera.[10][12] By November 2008, 15 device manufacturers had embed Snapdragon chips in their consumer electronics products.[13][14][15]

In November 2008, a techdemo processor and netbook was showcased. The processor consumed less power than the contemporary Intel Atom Z500 and was claimed to be more cost-effective when released.[16][17][18] The netbook used 1.5 GHz processors and was intended for developing markets.[14][19][20]

In collaboration with Sun, Java SE received Snapdragon-specific optimizations in May 2009.[21] Qualcomm started using 45nm process for SoC productions in late 2009.[22][23]

By June 2010, Snapdragon chips were incorporated into 120 product designs in development.[24] The company announced the MSM8960[25][26] for LTE networks that november.[27]

Apple had a dominant market position for smartphones at the time and did not incorporate Snapdragon into any of its products. The success of Snapdragon therefore relied on competing Android phones.[24][28][29][30]

Support for the Windows Phone 7 operating systems was added to Snapdragon in October 2010.[29]

By 2011 Snapdragon was embedded in Hewlett Packard's WebOS devices[31] and had a 50% market share of a $7.9 billion smartphone processor market.[clarification needed][32]

As of July 2014 Qualcomm's Snapdragon chips were embedded in 41% of smartphones.[33]

Snapdragon chips are also used in Android-based smartwatches,[34] and in vehicles like the Maserati Quattroporte and Cadillac XTS.[35]

In early 2011, Qualcomm announced Krait,[36] an in-house CPU microarchitecture design supporting the ARM v7 instruction set. SoCs featuring Krait were named S4 supports asynchronous symmetrical multi-processing (aSMP), meaning each processor core adjusted its clock speed and voltage based on the device's activity in order to optimize battery usage.[2] Prior models were renamed to S1, S2 and S3 to distinguish between each generation.[37]

The S4-based generation of Snapdragon SoCs began shipping to product manufacturers with the MSM8960 in February 2012.[38] In benchmark tests by Anandtech, the MSM8960 had better performance than any other processor tested. In an overall system benchmark, the 8960 obtained a score of 907, compared to 528 and 658 for the Galaxy Nexus and HTC Rezound respectively.[39] In a Quadrant benchmark test, which assesses raw processing power, a dual-core Krait processor had a score of 4,952, whereas the quad-core Tegra 3 was just under 4,000.[40] The quad-core version, APQ8064, was made available in July 2012. It was the first Snapdragon SoC to use Qualcomm's Adreno 320 graphics processing unit (GPU).[41]

Adoption of Snapdragon contributed to Qualcomm's transition from a wireless modem company to one that also produces a wider range of hardware and software for mobile devices.[42] In July 2011 Qualcomm acquired certain assets from GestureTek in order to incorporate its gesture recognition intellectual property into Snapdragon SoCs.[43] In mid-2012 Qualcomm announced the Snapdragon software development kit (SDK) for Android devices at the Uplinq developer conference.[44] The SDK includes tools for facial recognition, gesture recognition, noise cancellation and audio recording.[44] That November Qualcomm acquired some assets from EPOS Development in order to integrate its stylus and gesture recognition technology into Snapdragon products.[45] It also collaborated with Microsoft to optimize Windows Phone 8 for Snapdragon semiconductors.[46]

By 2012, the Snapdragon S4 (Krait core) had taken a dominant share from other Android system-on-chips like Nvidia Tegra and Texas Instruments OMAP which caused the latter to exit the market.[47] As of July 2014, the market share of Android phones had grown to 84.6 percent,[48] and Qualcomm's Snapdragon chips powered 41% of smartphones.[33]

Snapdragon SoCs are also used in most Windows phones[46] and most phones entering the market in mid-2013.[49]

2014–present: 64-bit ARM

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The debut of Apple's 64-bit A7 chip in the iPhone 5S forced Qualcomm to rush out a competing 64-bit solution, despite the capable performance of the Snapdragon 800/801/805, since their existing Krait cores were only 32-bit.[50] The first 64-bit SoCs, the Snapdragon 808 and 810, were rushed to market and released in 2014 using Cortex-A57 and Cortex-A53 cores. They suffered from overheating problems and throttling, particularly the 810, which led to Samsung ditching Snapdragon for its Galaxy S6 flagship phone.[51][52]

The entry-level 200 series was expanded with six new processors using 28 nanometer manufacturing and dual or quad-core options in June 2013.[53]

In February 2015, Qualcomm re-branded its stand-alone modem products under the Snapdragon name; they were distinguished from SoCs using the "x" designation, such as the X7 or X12 modem.[54]

In early 2016, Qualcomm launched the Snapdragon 820, an ARM 64-bit quad-core processor using in-house designed Kryo cores. A higher clocked variant is available as the Snapdragon 821. The SoC uses Samsung's 14-nanometer FinFET process. Together released is the Neural Processing Engine SDK supporting AI acceleration.[55]

The first Snapdragon modem for 5G networks, the X50, was announced in October 2016 and released in late 2019.[56][57]

The octa-core Snapdragon 835 SoC is announced on 17 November 2016. It uses modified Cortex-A73 and A53 cores and is built using Samsung's 10 nanometer FinFET process.[58]

At Computex 2017 in May, Qualcomm and Microsoft announced plans to launch Snapdragon-based laptops running Windows 10. Qualcomm partnered with HP, Lenovo, and Asus to release slim portables and 2-in-1 devices powered by the Snapdragon 835.[59]

Snapdragon 845 uses updated Cortex-A75 and A55 CPU, and the same 10-nanometer manufacturing process as 835.[60]

The 7 series is introduced in early 2018, targeting pricing and performances between the 6 and 8 series.[61][62][63]

As of 2018,[update] Asus, HP and Lenovo have begun selling laptops with Snapdragon-based CPUs running Windows 10 on ARM under the name "Always Connected PCs".

The Snapdragon 855 was released in 2019 and built on TSMC's 7 nanometer process.[64]

The Snapdragon 865 supported 5G celluar network through a separate X55 modem. The 765 has integrated 5G.[65][66]

The Snapdragon 888 announced in December 2020 is the first Qualcomm SoC to feature ARM's Cortex-X series CPU architecure.[67]

NASA's Ingenuity helicopter, which landed on Mars in 2021, has a Snapdragon 801 processor integrated onboard.[68]

The Snapdragon 8 Gen 2 added support for Wi-Fi 7.

Description and current models

[edit] Main article: List of Qualcomm Snapdragon processors

This section needs to be updated. The reason given is: Outdated architecture and naming scheme information. Please help update this article to reflect recent events or newly available information. (October 2024)

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Snapdragon system on chip products typically include a graphics processing unit (GPU), a global positioning system (GPS) and an (optional) cellular modem integrated into a single package.[69] It has software included that operates graphics, video and picture-taking.[70]

The current Snapdragon naming scheme was implemented after the announcement of Snapdragon 800 family in 2013. Models prior to it were renamed to the 200, 400 or 600 series.[71][72] The former two targeting entry-level products, while the 600 and 800 targeting mid-range and high-end products, respectively.[54][73]

The Snapdragon 805 was released in November 2013.[74] The 410, which is intended for low-cost phones in developing nations, was announced the following month.[75] In January 2014, Qualcomm introduced a modified version of the Snapdragon 600 called 602A[76] that is intended for in-car infotainment screens, backup cameras, and other driver assistance products.[77] The quad-core Snapdragon 610 and eight-core 615 were announced in February 2014.[78] The Snapdragon 808 and 810 were announced in April 2014.[79] The Snapdragon 835, announced in November 2017, is the first Qualcomm SOC that is built on a 10 nm architecture.[80] Qualcomm's new flagship chip for 2018, the 845, was announced in December 2017. According to Qualcomm, the 845 is 25-30% faster than the 835.

In 2017 the 660 and 630 replaced the 653 and 626 mid-range models[81] and several chips in the 400 product family were revised.[82][83] In February 2017, Qualcomm introduced the Snapdragon X20 celluar modem, intended for 5G cell phone networks,[84] and two new chips for 802.11ax commercial Wi-Fi networks.[85] This was followed by the addition of the 636 to the 600 product family that October, which Qualcomm said would be 40 percent faster than the 630.[86]

The 8cx series are SoCs designed for Windows laptops.[87] The first generation 8cx featured two CPU clusters consisting of four Cortex-A76 and A55 CPU cores, respectively.[88] Compared to the comtemporary 855, the first 8cx has a larger 10MB L3 cache and double the GPU floating point performance.[89]

Sponsoring

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Snapdragon is to be the primary shirt sponsor for English football club Manchester United starting with the 2024–25 season, replacing the German company TeamViewer.[90]

The brand also holds naming rights for Snapdragon Stadium in San Diego. The stadium will host San Diego FC of Major League Soccer (MLS) starting in 2025.

See also

[edit]

• List of Qualcomm Snapdragon processors
• Adreno
• Qualcomm Hexagon
• Snapdragon Stadium

References

[edit]

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Further reading

[edit]

• Boxall, Andy (24 January 2015). "When cities adopt smartphone chips, trash cans talk and street lamps have ears". Digital Trends.

External links

[edit] Wikimedia Commons has media related to Snapdragon (microprocessor).

• Official website

v t e ARM-based chips

v t e Application ARM-based chips Arm ARM architecture family List of ARM processors List of products using ARM processors ARM Cortex-A ARM Cortex-R ARM Cortex-M Comparison of ARM processors Applicationprocessors(32-bit) ARMv7-A Cortex-A5 Actions ATM702x Amlogic M805/S805, T82x Atmel SAMA5D3 InfoTM iMAPx820, iMAPx15 Qualcomm Snapdragon S4 Play, 200 RDA RDA8810PL Telechips TCC892x Cortex-A7 Allwinner A2x, A3x, A83T, H3, H8 NXP i.MX7, QorIQ LS10xx, NXP i.MX6UL Broadcom VideoCore BCM2836, BCM23550 Leadcore LC1813, LC1860/C, LC1913, LC1960 Marvell Armada PXA1920, 1500 mini plus MediaTek MT65xx Qualcomm Snapdragon 200, 205, 208, 210, 212, 400 Cortex-A8 Allwinner A1x Apple A4 Freescale i.MX5 Rockchip RK291x Samsung Exynos 3110(S5PC110), S5PV210 Texas Instruments OMAP 3 Texas Instruments Sitara AM3xxx Texas Instruments DM38x ZiiLABS ZMS-08 Cortex-A9 Actions ATM702x, ATM703x Altera Cyclone V, Arria V/10 Amlogic AML8726, MX, M6x, M801, M802/S802, S812, T86x Apple A5, A5X Broadcom VideoCore BCM21xxx, BCM28xxx Freescale i.MX6 HiSilicon K3V2, 910's InfoTM iMAPx912 Leadcore LC1810, LC1811 Marvell Armada 1500 mini MediaTek MT65xx Nvidia Tegra, 2, 3, 4i Nufront NuSmart 2816M, NS115, NS115M Renesas EMMA EV2, R-Car H1, RZ/A Rockchip RK292x, RK30xx, RK31xx Samsung Exynos 4 421x, 441x ST-Ericsson NovaThor Telechips TCC8803 Texas Instruments OMAP 4 Texas Instruments Sitara AM4xxx VIA WonderMedia WM88x0, 89x0 Xilinx Zynq-7000 ZiiLABS ZMS-20, ZMS-40 Cortex-A15 Allwinner A80 HiSilicon K3V3 MediaTek MT8135/V Nvidia Tegra 4, K1 Renesas R-Car H2 Samsung Exynos 5 52xx, 54xx Texas Instruments OMAP 5, DRA7xx, AM57xx Texas Instruments Sitara AM5xxx Cortex-A17 MediaTek MT6595, MT5595 MStar 6A928 Rockchip RK3288 Others Cortex-A12 ARMv7-Acompatible Apple A6, A6X, S1, S1P, S2, S3 Broadcom Brahma-B15 Marvell P4J Qualcomm Snapdragon S1, S2, S3, S4 Plus, S4 Pro, 600, 800 (Scorpion, Krait) ARMv8-A Others Cortex-A32 Applicationprocessors(64-bit) ARMv8-A Cortex-A35 NXP i.MX8X MediaTek MT6799, MT8516 Rockchip RK3308 Cortex-A53 Actions GT7, S900, V700 Allwinner A64, H5, H64, R18 Altera Stratix 10 Amlogic S9 Family, T96x Broadcom BCM2837 EZchip TILE-Mx100 HiSilicon Kirin 620, 650, 655, 658, 659, 930, 935 Marvell Armada PXA1928, Mobile PXA1908/PXA1936 MediaTek MT673x, MT675x, MT6761V, MT6762/V, MT6763T, MT6765/G/H, MT6795, MT8161, MT8163, MT8165, MT8732, MT8735, MT8752 NXP ARM S32, QorIQ LS1088, LS1043, i.MX8M Qualcomm Snapdragon 215, 410, 412, 415, 425, 427, 429, 430, 435, 439, 450, 610, 615, 616, 617, 625, 626, 630 Renesas RZ/V2M Rockchip RK3328, RK3368 Samsung Exynos 7570, 7578, 7580, 7870, 7880 Texas Instruments Sitara AM6xxx UNISOC SC9820E, SC9832E, SC9860/GV Xilinx ZynqMP Cortex-A57 AMD Opteron A1100-series NXP QorIQ LS20xx Nvidia Tegra X1 and Tegra X2 Qualcomm Snapdragon 808 and 810 Samsung Exynos 7 5433, 7420 HiSilicon Kirin Hi1610 and Hi1612 Cortex-A72 AWS Graviton Broadcom BCM2711 HiSilicon Kirin 950, 955, Kunpeng 916 MediaTek MT6797/D/T/X, MT8173, MT8176, MT8693 MStar 6A938 Qualcomm Snapdragon 650, 652, 653 Rockchip RK3399 NXP QorIQ LS2088, QorIQ LS1046A, QorIQ LX2160A, QorIQ LS1028A, i.MX8 Cortex-A73 Qualcomm Snapdragon 460, 632, 636, 660, 662, 665, 680, 685, 6s 4G Gen 1, 835 Samsung Exynos 7872, 7884, 7885, 7904, 9609, 9610, 9611 HiSilicon Kirin 710, 960, 970 MediaTek MT6771/V, MT6799, MT8183, MT8788 Amlogic S922X Others Cortex-A34 ARMv8-Acompatible Ampere eMAG Apple A7, A8, A8X, A9, A9X, A10, A10X Applied Micro X-Gene Cavium ThunderX Nvidia Tegra K1 (Denver), Tegra X2 (Denver2) Qualcomm Kryo, Falkor Samsung Exynos M1 (Mongoose), M2 (Mongoose) ARMv8.1-A ARMv8.1-Acompatible Cavium ThunderX2 ARMv8.2-A Cortex-A55 Allwinner A523 Samsung Exynos 850 UNISOC SC9863/A, T603 Cortex-A75 Qualcomm Snapdragon 670, 710, 712, 845, 850 Samsung Exynos 9820, 9825 MediaTek MT6769H/T/V/Z, MT6768, MT6779V UNISOC T310, T606, T610, T615, T616, T618, T619, T620, T700, T710, T7200, T7225, T7250, T7255, T7280, T740 Cortex-A76 Allwinner A733 Google Tensor HiSilicon Kirin 810, 820, 980, 985, 990 Qualcomm Snapdragon 480(+), 675, 678, 720G, 730(G), 732G, 765(G), 768G, 855(+), 860, 7c (Gen 2), 8c, 8cx (Gen 2) Microsoft SQ1 and SQ2 MediaTek MT6781, MT6785V, MT6789, MT6833V/P, MT6853V/T, MT6873, MT6875, Dimensity 6020, 6080, 6100+, 6300(+), MT8192 Samsung Exynos 990 UNISOC T750, T760, T765, T770, T820, T8100, T8200, T9100 Cortex-A77 MediaTek Dimensity 1000(+) Qualcomm Snapdragon 690, 750G, 865(+), 870 HiSilicon Kirin 9000 Samsung Exynos 880, 980 Cortex-A78 Google Tensor G2 MediaTek MT6877, MT6878, MT6879, MT6891, MT6893, Dimensity 7020, 7025(Ultra), 7030, 7050, 7300(Energy/X), 8000, 8020, 8050, 8100, 8200, Kompanio 900T, 1200, 1380, 1300T Qualcomm Snapdragon 4 Gen 1, 4(s) Gen 2, 695, 6 Gen 1, 6(s) Gen 3, 778G(+), 780G, 782G, 888(+) Samsung Exynos 1080, 1280, 1330, 1380, 2100 Cortex-X1 Google Tensor, Tensor G2 Qualcomm Snapdragon 888(+) Samsung Exynos 2100 Neoverse N1 Ampere Altra, Altra Max AWS Graviton2 Others Cortex-A65, Cortex-A65AE, Cortex-A76AE, Cortex-A78C, Cortex-X1C, Neoverse E1 ARMv8.2-Acompatible Apple A11 Fujitsu A64FX HiSilicon TaiShan v110 Nvidia Tegra Xavier (Carmel) Samsung Exynos M3 (Meerkat), M4 (Cheetah), M5 (Lion) ARMv8.3-A ARMv8.3-Acompatible Apple A12, A12X/A12Z, S4, S5 Marvell ThunderX3 ARMv8.4-A Neoverse V1 AWS Graviton3 ARMv8.4-Acompatible Apple A13, S6, S7, S8 ARMv8.5-A ARMv8.5-Acompatible Apple A14, M1 ARMv8.6-A ARMv8.6-Acompatible Apple A15, A16, A17, M2, M3 ARMv8.7-A ARMv8.7-Acompatible Qualcomm Oryon ARMv9.0-A Cortex-A510 Google Tensor G3 MediaTek Dimensity 7200 (Pro/Ultra), 8300 (Ultra), 9000/9000+, 9200 Qualcomm Snapdragon 7 Gen 1, 7 Gen 3, 7s/7+ Gen 2, 8(+) Gen 1, 8 Gen 2 Samsung Exynos 2200 Cortex-A710 MediaTek Dimensity 9000/9000+ Qualcomm Snapdragon 7 Gen 1, 7 Gen 3, 7s/7+ Gen 2, 8(+) Gen 1, 8 Gen 2 Samsung Exynos 2200 Cortex-A715 Google Tensor G3 MediaTek Dimensity 7200 (Pro/Ultra), 8300 (Ultra), 9200 Qualcomm Snapdragon 7 Gen 3, 8 Gen 2 Cortex-X2 MediaTek Dimensity 9000/9000+ Qualcomm Snapdragon 7s/7+ Gen 2, 8(+) Gen 1 Samsung Exynos 2200 Cortex-X3 Google Tensor G3 MediaTek Dimensity 9200/9200+ Qualcomm Snapdragon 8 Gen 2 Neoverse N2 Alibaba YiTian 710 Microsoft Azure Cobalt 100 Neoverse V2 AWS Graviton4 Google Axion Nvidia Grace ARMv9.2-A Cortex-A520 Google Tensor G4 Qualcomm Snapdragon 7s/7+ Gen 3, Snapdragon 8(s) Gen 3 Samsung Exynos 2400 Cortex-A720 Google Tensor G4 MediaTek Dimensity 9300(+) Qualcomm Snapdragon 7s/7+ Gen 3, Snapdragon 8(s) Gen 3 Samsung Exynos 2400 Cortex-X4 Google Tensor G4 MediaTek Dimensity 9300(+) Qualcomm Snapdragon 7+ Gen 3, Snapdragon 8(s) Gen 3 Samsung Exynos 2400 Cortex-X925 MediaTek Dimensity 9400(+) Neoverse N3 - Neoverse V3 - ARMv9.2-Acompatible Apple A18 Apple M4 v t e Embedded ARM-based chips ARM Holdings ARM architecture family List of ARM cores ARM Cortex-A ARM Cortex-R ARM Cortex-M List of ARM Cortex-M development tools Embeddedmicrocontrollers Cortex-M0 Cypress PSoC 4000, 4100, 4100M, 4200, 4200DS, 4200L, 4200M Infineon XMC1000 Nordic nRF51 NXP LPC1100, LPC1200 nuvoTon NuMicro Sonix SN32F700 STMicroelectronics STM32 F0 Toshiba TX00 Vorago VA108x0 Cortex-M0+ Cypress PSoC 4000S, 4100S, 4100S+, 4100PS, 4700S, FM0+ Holtek HT32F52000 Microchip (Atmel) SAM C2, D0, D1, D2, DA, L2, R2, R3 NXP LPC800, LPC11E60, LPC11U60 NXP (Freescale) Kinetis E, EA, L, M, V1, W0 Raspberry Pi RP2040 Renesas Synergy S1 Silicon Labs (Energy Micro) EFM32 Zero, Happy STMicroelectronics STM32 L0 Cortex-M1 Altera FPGAs Cyclone-II, Cyclone-III, Stratix-II, Stratix-III Microsemi (Actel) FPGAs Fusion, IGLOO/e, ProASIC3L, ProASIC3/E Xilinx FPGAs Spartan-3, Virtex-2-3-4 Cortex-M3 Actel SmartFusion, SmartFusion 2 Analog Devices ADuCM300 Cypress PSoC 5000, 5000LP, FM3 Fujitsu FM3 Holtek HT32F Microchip (Atmel) SAM 3A, 3N, 3S, 3U, 3X NXP LPC1300, LPC1700, LPC1800 ON Semiconductor Q32M210 Silicon Labs Precision32 Silicon Labs (Energy Micro) EFM32 Tiny, Gecko, Leopard, Giant STMicroelectronics STM32 F1, F2, L1 Texas Instruments F28, LM3, TMS470, OMAP 4 Toshiba TX03 Cortex-M4 Microchip (Atmel) SAM 4L, 4N, 4S NXP (Freescale) Kinetis K, W2 Renesas RA4W1, RA6M1, RA6M2, RA6M3, RA6T1 Cortex-M4F Cypress 6200, FM4 Infineon XMC4000 Microchip (Atmel) SAM 4C, 4E, D5, E5, G5 Microchip CEC1302 Nordic nRF52 NXP LPC4000, LPC4300 NXP (Freescale) Kinetis K, V3, V4 Renesas Synergy S3, S5, S7 Silicon Labs (Energy Micro) EFM32 Wonder STMicroelectronics STM32 F3, F4, L4, L4+, WB Texas Instruments LM4F/TM4C, MSP432 Toshiba TX04 Cortex-M7F Microchip (Atmel) SAM E7, S7, V7 NXP (Freescale) Kinetis KV5x, i.MX RT 10xx, i.MX RT 11xx, S32K3xx STMicroelectronics STM32 F7, H7 Cortex-M23 GigaDevice CD32E2xx Microchip (Atmel) SAM L10, L11, and PIC 32CM-LE 32CM-LS Nuvoton M23xx family, M2xx family, NUC1262, M2L31 Renesas S1JA, RA2A1, RA2L1, RA2E1, RA2E2 Cortex-M33F Analog Devices ADUCM4 Dialog DA1469x GigaDevice GD32E5, GD32W5 Nordic nRF91, nRF5340, nRF54 NXP LPC5500, i.MX RT600 ON RSL15 Renesas RA4, RA6 ST STM32 H5, L5, U5, WBA Silicon Labs Wireless Gecko Series 2 Cortex-M35P STMicroelectronics ST33K Cortex-M55F Alif Semiconductor Ensemble Infineon PSoC Edge Cortex-M85F Renesas RA8 Real-timemicroprocessors Cortex-R4F Texas Instruments RM4, TMS570 Renesas RZ/T1 Cortex-R5F Scaleo OLEA Texas Instruments RM57, AM2 Xilinx Versal, ZynqMP, ZynqRF Cortex-R7F Renesas RZ/G2E, RZ/G2H, RZ/G2M, RZ/G2N Cortex-R52F NXP S32Z, S32E Renesas RZ/N2L, RZ/T2L, RZ/T2M Cortex-R52+F STMicroelectronics Stellar G, Stellar P v t e Classic ARM-based chips ARM Holdings ARM architecture family List of ARM cores ARM Cortex-A ARM Cortex-R ARM Cortex-M List of ARM Cortex-M development tools Classicprocessors ARM7 Atmel SAM7L, SAM7S, SAM7SE, SAM7X, SAM7XC, AT91CAP7, AT91M, AT91R Cirrus Logic PS7xxx, EP7xxx Mediatek MT62xx NXP LPC2100, LPC2200, LPC2300, LPC2400, LH7 STMicroelectronics STR7 ARM9 Aspeed AST2400 Atmel SAM9G, SAM9M, SAM9N, SAM9R, SAM9X, SAM9XE, SAM926x, AT91CAP9 Cirrus Logic EP9xxx Freescale i.MX1x, i.MX2x Nuvoton NUC900 NXP LPC2900, LPC3000, LH7A Philips Nexperia PNX4008 Rockchip RK27xx, RK28xx Samsung S3C24xx STMicroelectronics Nomadik STn881x STMicroelectronics STR9 Texas Instruments OMAP 1, AM1x, DaVinci VIA WonderMedia WM8505/8650 ZiiLABS ZMS-05 ARM11 Broadcom BCM2835 Cavium CNS3xxx Freescale i.MX3x Infotmic IMAPX210/220 Mindspeed Comcerto 1000 Nvidia Tegra APX, 6xx Qualcomm MSM7000, Snapdragon S1 Samsung S3C64xx, S5P64xx ST-NXP Wireless Nomadik STn882x Telechips TCC8902 Texas Instruments OMAP 2 VIA WonderMedia WM87x0 ARMv2acompatible Amber (open FPGA core) ARMv4compatible Faraday FA526, FA626 DEC/Intel StrongARM ARMv5TEcompatible Intel/Marvell XScale Marvell Sheeva, Feroceon, Jolteon, Mohawk Faraday FA606TE, FA616TE, FA626TE, FA726TE

v t e Single-board computer and single-board microcontroller
Devices	Arduino Arndale Board Asus Tinker Board Banana Pi BeagleBoard Cotton Candy CHIP Cubieboard Edison Galileo Gumstix Hawkboard IGEPv2 LattePanda Nvidia Drive Nano Pi Nvidia Jetson ODROID OLinuXino PandaBoard Pine64 Parallella Rascal Raspberry Pi Snowball UDOO Vaaman
SoCs	ARM Actions Allwinner Ax Apple M1 Exynos i.MX HiSiliconK3V3 MediaTek Nomadik NovaThor OMAP Rockchip Qualcomm Snapdragon Tegra WonderMedia MIPS Jz x86/x86-64 AMD Élan Atom Jaguar-based Puma-based Quark
Software	Apache Hadoop Linaro