ARM Cortex-A15

ARM Cortex-A15

Produced	In production late 2011,^[1] to market late 2012^[2]
Designed by	ARM Holdings
Max. CPU clock rate	1.0 GHz to 2.5 GHz
Min. feature size	32 nm/28 nm initially^[3] to 22 nm roadmap^[3]
Microarchitecture	ARMv7-A
Cores	1–4 per cluster, 1–2 clusters per physical chip^[4]
L1 cache	64 KB (32 KB I-cache, 32 KB D-cache) per core
L2 cache	Up to 4 MB^[5] per cluster
L3 cache	none

The ARM Cortex-A15 MPCore is a 32-bit processor core licensed by ARM Holdings implementing the ARMv7-A architecture. It is a multicore processor with out-of-order superscalar pipeline running at up to 2.5 GHz.^[6]

Overview

Main article: Comparison of ARMv7-A cores

ARM has claimed that the Cortex A15 core is 40 percent more powerful than the Cortex-A9 core with the same number of cores at the same speed.^[7] The first A15 designs came out in the autumn of 2011, but products based on the chip did not reach the market until 2012.^[1]

Key features of the Cortex-A15 core are:

40-bit Large Physical Address Extensions (LPAE) addressing up to 1 TB of RAM.^[8]^[9] As per the x86 Physical Address Extension, virtual address space remains 32 bit.^[10]
15 stage integer/17–25 stage floating point pipeline, with out-of-order speculative issue 3-way superscalar execution pipeline^[11]
4 cores per cluster, up to 2 clusters per chip with CoreLink 400 (CCI-400, an AMBA-4 coherent interconnect) and 4 clusters per chip with CCN-504.^[12] ARM provides specifications but the licencees individually design ARM chips, and AMBA-4 scales beyond 2 clusters. The theoretical limit is 16 clusters; 4 bits are used to code the CLUSTERID number in the CP15 register (bits 8 to 11).^[13]
DSP and NEON SIMD extensions onboard (per core)
VFPv4 Floating Point Unit onboard (per core)
Hardware virtualization support
Thumb-2 instruction set encoding to reduce the size of programs with little impact on performance
TrustZone security extensions
Jazelle RCT for JIT compilation
Program Trace Macrocell and CoreSight Design Kit for unobtrusive tracing of instruction execution
32 KB data + 32 KB instruction L1 cache per core
Integrated low-latency level-2 cache controller, up to 4 MB per cluster

Chips

First implementation came from Samsung in 2012 with the Exynos 5 Dual, which shipped in October 2012 with the Samsung Chromebook Series 3 (ARM version), followed in November by the Google Nexus 10.

Press announcements of current implementations:

Broadcom SoC^[14]
HiSilicon K3V3^[15]
Nvidia Tegra 4 (Wayne)^[16] and Tegra K1.
Samsung Exynos 5 Dual, Quad and Octa^[17]
ST-Ericsson Nova A9600 (cancelled) (dual-core @ 2.5 GHz over 20k DMIPS)^[18]^[19]
Texas Instruments OMAP 5 SoCs^[20] and Sitara AM57x family^[21]

Other licensees, such as LG,^[22]^[23] are expected to produce an A15 based design at some point.

Systems on a chip

Model Number	Semiconductor technology	CPU	GPU	Memory interface	Wireless radio technologies	Availability	Utilizing devices
HiSilicon K3V3	28 nm HPL	big.LITTLE architecture using 1.8 GHz dual-core ARM Cortex-A15 + dual-core ARM Cortex-A7	Mali-T628			H2 2014
Nvidia Tegra 4 T40	28 nm HPL	1.9 GHz quad-core ARM Cortex-A15^[24] + 1 low power core	Nvidia GeForce @ 72 core, 672 MHz, 96.8 GFLOPS = 48 PS + 24 VU × 0.672 × 2 (96.8 GFLOPS)^[25](support DirectX 11+, OpenGL 4.X, and PhysX)	32-bit dual-channel DDR3L or LPDDR3 up to 933 MHz (1866 MT/s data rate)^[24]	Category 3 (100 Mbit/s) LTE	Q2 2013	Nvidia Shield Tegra Note 7
Nvidia Tegra 4 AP40	28 nm HPL	1.2-1.8 GHz quad-core + low power core	Nvidia GPU 60 ^[24] cores (support DirectX 11+, OpenGL 4.X, and PhysX)	32-bit dual-channel 800 MHz LPDDR3	Category 3 (100 Mbit/s) LTE	Q3 2013
Nvidia Tegra K1	28 nm HPm	2.3 GHz quad-core + battery saver core	Kepler SMX (192 CUDA cores, 8 TMUs, 4 ROPs)	32-bit dual-channel DDR3L, LPDDR3 or LPDDR2		Q2 2014	Jetson TK1 development board,^[26] Lenovo ThinkVision 28, Xiaomi MiPad, Shield Tablet
Texas Instruments OMAP5430	28 nm	1.7 GHz dual-core	PowerVR SGX544MP2 @ 532 MHz + dedicated 2D graphics accelerator	32-bit dual-channel 532 MHz LPDDR2		Q2 2013	phyCore-OMAP5430^[27]
Texas Instruments OMAP5432	28 nm	1.5 GHz dual-core	PowerVR SGX544MP2 @ 532 MHz + dedicated 2D graphics accelerator	32-bit dual-channel 532 MHz DDR3		Q2 2013	SVTronics EVM,^[28] Compulab SBC-T54^[29]
Texas Instruments AM57x	28 nm	1.5 GHz single or dual-core	PowerVR SGX544MP2 @ 532 MHz + dedicated 2D graphics accelerator	32-bit dual-channel 532 MHz DDR3		Q4 2015	BeagleBoard x15, Elesar Titanium^[30]
Exynos 5 Dual^[31] (previously Exynos 5250)^[32]	32 nm HKMG	1.7 GHz dual-core ARM Cortex-A15	ARM Mali-T604^[33] (quad-core) @ 533 MHz; 68.224 GFLOPS	32-bit dual-channel 800 MHz LPDDR3/DDR3 (12.8 GB/sec) or 533 MHz LPDDR2 (8.5 GB/sec)		Q3 2012^[32]	Samsung Chromebook XE303C12,^[34] Google Nexus 10, Arndale Board,^[35] Huins ACHRO 5250 Exynos,^[36] Freelander PD800 HD,^[37] Voyo A15, HP Chromebook 11, Samsung Homesync
Exynos 5 Octa^[38]^[39]^[40] (internally Exynos 5410)	28 nm HKMG	1.6 GHz^[41] quad-core ARM Cortex-A15 and 1.2 GHz quad-core ARM Cortex-A7 (ARM big.LITTLE)^[42]	IT PowerVR SGX544MP3 (tri-core) @ 480 MHz 49 GFLOPS (532 MHz in some full-screen apps)^[43]	32-bit dual-channel 800 MHz LPDDR3 (12.8 GB/sec)		Q2 2013	Samsung Galaxy S4 I9500,^[44]^[45] Hardkernel ODROID-XU,^[46] Meizu MX3, ZTE Grand S II TD^[47] ODROID-XU
Exynos 5 Octa^[48] (internally Exynos 5420)	28 nm HKMG	1.8-1.9 GHz quad-core ARM Cortex-A15 and 1.3 GHz quad-core ARM Cortex-A7 (ARM big.LITTLE with GTS)	ARM Mali-T628 MP6 @ 533 MHz; 109 GFLOPS	32-bit dual-channel 933 MHz LPDDR3e (14.9 GB/sec)		Q3 2013	Samsung Chromebook 2 11.6",^[49] Samsung Galaxy Note 3,^[50] Samsung Galaxy Note 10.1 (2014 Edition), Samsung Galaxy Note Pro 12.2, Samsung Galaxy Tab Pro (12.2 & 10.1), Arndale Octa Board, Galaxy S5 SM-G900H ^[51]
Exynos 5 Octa^[52] (internally Exynos 5422)	28 nm HKMG	2.1 GHz quad-core ARM Cortex-A15 and 1.5 GHz quad-core ARM Cortex-A7 (ARM big.LITTLE with GTS)	ARM Mali-T628 MP6 @ 695 MHz (142 Gflops)	32-bit dual-channel 933 MHz LPDDR3/DDR3 (14.9 GB/sec)		Q2 2014	Galaxy S5 SM-G900, Hardkernel ODROID-XU3 & ODROID-XU4 ^[53]
Exynos 5 Octa^[54] (internally Exynos 5800)	28 nm HKMG	2.1 GHz quad-core ARM Cortex-A15 and 1.3 GHz quad-core ARM Cortex-A7 (ARM big.LITTLE with GTS)	ARM Mali-T628 MP6 @ 695 MHz (142 Gflops)	32-bit dual-channel 933 MHz LPDDR3/DDR3 (14.9 GB/sec)		Q2 2014	Samsung Chromebook 2 13,3"^[55]
Exynos 5 Hexa^[56] (internally Exynos 5260)	28 nm HKMG	1.7 GHz dual-core ARM Cortex-A15 and 1.3 GHz quad-core ARM Cortex-A7 (ARM big.LITTLE with GTS)	ARM Mali-T624	32-bit dual-channel 800 MHz LPDDR3 (12.8 GB/sec)		Q2 2014	Galaxy Note 3 Neo (announced January 31, 2014), Samsung Galaxy K zoom^[57]
Allwinner A80 Octa^[58]	28 nm HPm	Quad-core ARM Cortex-A15 and Quad-core ARM Cortex-A7 (ARM big.LITTLE with GTS)	PowerVR G6230 (Rogue)	32-bit dual-channel DDR3/DDR3L/LPDDR3 or LPDDR2^[59]

References

1 2 TI Reveals OMAP 5: The First ARM Cortex A15 SoC
↑ ARM Expects First Cortex-A15 Devices in Late 2012
1 2 ARM Unveils Cortex-A15 MPCore Processor to Dramatically Accelerate Capabilities of Mobile, Consumer and Infrastructure Applications — in the Supporting Technology section
↑ CoreLink Network Interconnect for AMBA AXI
↑ Cortex-A15 Processor — Product description
↑ ARM Cortex-A15 - ARM Processor
↑ Exclusive : ARM Cortex-A15 "40 Per Cent" Faster Than Cortex-A9
↑ ARM7 40-bit, virtualization
↑ ARM e-mail to LINUX: Add support for the Large Physical Address Extensions
↑ "Calxeda plots server dominance with ARM SoCs."
↑ Exploring the Design of the Cortex-A15 Processor Travis Lanier
↑ "ARM A15 web page, Specification tab"
↑ "Cortex-A15 MPCore Technical Reference Manual"
↑ Broadcom announces plans for ARM's Cortex-A15 SoC | thinq
↑ Huawei Announces HiSilicon K3V3 Chipset For Smartphones on Tom's Hardware
↑ NVIDIA Announces "Project Denver" to Build Custom CPU Cores Based on ARM Architecture, Targeting Personal Computers to Supercomputers - NVIDIA Newsroom
↑ Samsung Announces Industry First ARM Cortex-A15 Processor Samples for Tablet Computers
↑ Changing the game: ST-Ericsson Unveils NovaThor™ Family of Smartphone Platforms Combining its Most Advanced Application Processors with the Latest Generation of Modems
↑ Desire Athow (14 March 2011). "Exclusive : ARM Cortex-A15 "40 Per Cent" Faster Than Cortex-A9". Retrieved 2011-01-22.
↑ OMAP Applications Processors - OMAP 5 Platform
↑ TI disrupts the embedded market with the most powerful SoCs featuring real-time processing and multimedia
↑ LG Electronics Licenses ARM Processor Technology to Drive - ARM
↑ Why LG Getting ARM Cortex A15 License Is A Big Deal | ITProPortal.com
1 2 3 http://www.nvidia.com/object/tegra-4-processor.html
↑ http://www.359gsm.com/forum/viewtopic.php?f=127&t=13134&p=26833#p26833
↑ "Jetson TK1 development board".
↑ "The phyCORE-OMAP5430 System on Module". Retrieved 8 February 2016.
↑ "OMAP5432 EVM". Retrieved 8 February 2016.
↑ "TI OMAP5 System-on-Module (SoM)". Retrieved 8 February 2016.
↑ "Titanium motherboard + Linux operating system". Retrieved 8 February 2016.
↑ "Samsung Exynos 5 Dual". Products. Samsung Electronics Co.Ltd. Retrieved 7 October 2013.
1 2 "Samsung Announces Industry First ARM Cortex-A15 Processor Samples for Tablet Computers". News. Samsung Electronics Co.Ltd. 30 November 2011. Retrieved 7 October 2013.
↑ "Samsung Exynos 5 Dual (Exynos 5250) RISC Microprocessor User's Manual Revison 1.0" (PDF). Samsung Electronics Co. Ltd. October 2012. Retrieved 7 October 2013.
↑ "Samsung Chromebook". Google. Retrieved 7 October 2013.
↑ "ArndaleBoard.org". www.arndaleboard.org. Retrieved 7 October 2013.
↑ "휴인스". Huins.com. Retrieved 2013-07-10.
↑ "Freelander PD800 HD Dual Core Exynos 5250 Android 4.2 Tablet PC 9.7" Retina Capacitive Touch Screen 2048*1536 2GB/16GB BT White". GeekBuying.com. Retrieved 10 July 2013.
↑ "Samsung Highlights Innovations in Mobile Experiences Driven by Components, in CES Keynote". CES News. SAMSUNG. 9 January 2013. Retrieved 7 October 2013.
↑ "2013 International CES Keynote". Events. SAMSUNG. 9 January 2013. Retrieved 7 October 2013.
↑ Nguyen, Hubert (17 January 2013). "Samsung Exynos 5 Octa Specs & Details". Uberzigmo. Blogzilla LL:. Retrieved 7 October 2013.
↑ "New Samsung Exynos 5 Octa". Products. Samsung Electronics Co.Ltd. Retrieved 7 October 2013.
↑ "Big.LITTLE Processing with ARM Cortex-A15 & Cortex-A7" (PDF). Arm.com. Retrieved 7 October 2013.
↑ "Update on GPU Optimizations in Galaxy S 4". AnandTech. Retrieved 7 October 2013.
↑ "Samsung Galaxy S4 32 GB". CaCell. Retrieved 7 October 2013.
↑ "Your country will get Exynos or Snapdragon variant of the Galaxy S 4, we have the answer!". SamMobile.com. 20 March 2013. Retrieved 17 October 2013.
↑ "Products: Exynos5 Octa". Odroid Platform Developer. Hardkernel Co., Ltd. Retrieved 7 October 2013.
↑ "ZTE Grand S II TD". DeviceSpecifications. Retrieved 10 January 2014.
↑ "New Samsung Exynos 5 Octa". Products. Samsung Electronics Co.Ltd. Retrieved 7 October 2013.
↑ "Samsung Chromebook 2 11.6".
↑ "Samsung Galaxy Note 3 specs and features now official". Androidauthority.com. 4 September 2013. Retrieved 7 October 2013.
↑ https://www.samsungindiaestore.com/products/mobiles/Galaxy_S5_SM-G900HZWA
↑ "Samsung Unveils New Products from its System LSI Business at Mobile World Congress". Samsung Tomorrow. Retrieved 26 February 2013.
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External links

Application ARM-based chips

Application
Processors
(32-bit)

Cortex-A5	Actions ATM702x Amlogic M805/S805 Atmel SAMA5D3 InfoTM iMAPx820, iMAPx15 Qualcomm Snapdragon S4 Play, 200 Telechips TCC892x

Cortex-A7	Allwinner A2x, A3x, A83T, H3, H8 Broadcom VideoCore BCM2836, BCM23550 Freescale QorIQ LS10xx Leadcore LC1813, LC1913 Marvell Armada PXA1920 MediaTek MT65xx Qualcomm Snapdragon 200, 400

Cortex-A8	Allwinner A1x Apple A4 Freescale i.MX5x Rockchip RK291x Samsung Exynos 3110, S5PC110, S5PV210 Texas Instruments OMAP 3 ZiiLABS ZMS-08

Cortex-A9	Actions ATM702x, ATM703x Altera Cyclone V, Arria V/10 Amlogic AML8726, MX, M6x, M801, M802/S802, S812, T866 Apple A5, A5X Broadcom VideoCore BCM21xxx, BCM28xxx Freescale i.MX6x HiSilicon K3V2 InfoTM iMAPx912 Leadcore LC1810, LC1811 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 ST-Ericsson NovaThor Telechips TCC8803 Texas Instruments OMAP 4 VIA WonderMedia WM88x0, 89x0 Xilinx Zynq-7000 ZiiLABS ZMS-20, ZMS-40

Cortex-A15	Allwinner A80 HiSilicon K3V3 MediaTek MT6599 Nvidia Tegra 4, K1 Renesas R-Car H2 Samsung Exynos 5 Texas Instruments OMAP 5, DRA7xx

Cortex-A17	MediaTek MT6595 Rockchip RK3288

ARMv7-A compatible	Apple A6, A6X Broadcom Brahma-B15 Marvell P4J Qualcomm Snapdragon S1, S2, S3, S4 Plus, S4 Pro, 600, 800 (Scorpion, Krait)

Application
Processors
(64-bit)

Cortex-A53	Actions S900 Allwinner A64, H64 Altera Stratix 10 Amlogic S905 EZchip TILE-Mx100 Marvell Armada PXA1928, Mobile PXA1908/PXA1936 MediaTek MT673x, MT675x, MT6795, MT8732, MT8752, Helio X10 Qualcomm Snapdragon 410 Rockchip RK3368 Xilinx ZynqMP

Cortex-A57	AMD Opteron A1100 Freescale QorIQ LS20xx Nvidia Tegra X1 Qualcomm Snapdragon 808, 810 Samsung Exynos 7

Cortex-A72	MediaTek Helio X20 Qualcomm Snapdragon 650, 652 HiSilicon Kirin 950

ARMv8-A compatible	Apple A7, A8, A8X, A9, A9X Applied Micro X-Gene Samsung Mongoose Cavium ThunderX CN87xx, CN88xx Nvidia Tegra K1 (Project Denver) Qualcomm Snapdragon 820 (Kryo)

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