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^ CPU and GPU frequencies are adjustable in BIOS.<ref>http://www.amd.com/us/Documents/Kyoto2150_QRG.pdf |
^ CPU and GPU frequencies are adjustable in BIOS.<ref>{{cite web|url=http://www.amd.com/us/Documents/Kyoto2150_QRG.pdf |title=Archived copy |accessdate=July 15, 2013 |deadurl=yes |archiveurl=http://web.archive.org/web/20130616051752/http://www.amd.com:80/us/Documents/Kyoto2150_QRG.pdf |archivedate=June 16, 2013 }}</ref> |
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=== Embedded === |
=== Embedded === |
Revision as of 01:31, 27 March 2016
General information | |
---|---|
Launched | Mid-2013 |
Discontinued | present |
Common manufacturer | |
Cache | |
L1 cache | 64 KB per core[1] |
L2 cache | 1 MB to 2 MB shared |
Architecture and classification | |
Technology node | 28 nm |
Instruction set | AMD64 (x86-64) |
Physical specifications | |
Sockets |
|
Products, models, variants | |
Core names |
|
History | |
Predecessor | Bobcat - Family 14h |
Successor | Puma - Family 16h (2nd-gen) |
The AMD Jaguar Family 16h is a low-power microarchitecture designed by AMD, and used in APUs succeeding the Bobcat Family microarchitecture in 2013 and being succeeded by AMD's Puma architecture in 2014. It is two-way superscalar and capable of out of order execution. It is used in AMD's Semi-Custom Business Unit as a design for custom processors and is used by AMD in four product families: Kabini aimed at notebooks and mini PCs, Temash aimed at tablets, Kyoto aimed at micro-servers, and the G-Series aimed at embedded applications. Both the PlayStation 4 and the Xbox One use chips based on the Jaguar microarchitecture, with more powerful GPUs than AMD sells in its own commercially available Jaguar APUs.[2]
Design
- 32 KiB instruction + 32 KiB data L1 cache per core, L1 cache includes parity error detection
- 16 way, 1-2 MiB unified L2 cache shared by two or four cores, L2 cache is protected from errors by the use of error correcting code
- Out-of-order execution and Speculative execution
- Integrated memory controller
- Two-way integer execution
- Two-way 128-bit wide floating-point and packed integer execution
- Integer hardware divider
- Consumer processors support 2 DDR3L DIMMs in one channel at frequencies up to 1600 MHz[3]
- Server processors support 2 DDR3 DIMMS in one channel at frequencies up to 1600 MHz with ECC[4]
- As a SoC (not just an APU) it integrates Fusion controller hub
- Jaguar does not feature clustered multi-thread (CMT), meaning that execution resources are not shared between cores
Instruction set support
The Jaguar core has support for the following instruction sets and instructions: MMX, SSE, SSE2, SSE3, SSSE3, SSE4a, SSE4.1, SSE4.2, AVX, F16C, CLMUL, AES, BMI1, MOVBE (Move Big-Endian instruction), XSAVE/XSAVEOPT, ABM (POPCNT/LZCNT), and AMD-V.[1]
Improvements over Bobcat
- Over 10% increase in clock frequency[5]
- Over 15% improvement in instructions per clock (IPC)[5]
- Added support for SSE4.1, SSE4.2, AES, CLMUL, MOVBE, AVX, F16C, and BMI1[5]
- Up to 4 CPU cores
- L2 cache is shared between cores
- FPU datapath width increased to 128 bit[5]
- Added hardware integer divider
- Enhanced cache prefetchers
- Doubled bandwidth of load-store units
- C6 and CC6 low power states with lower entry and exit latency[5]
- Smaller, 3.1 mm2 area per core
- Integrated Fusion controller hub (FCH)
- Video Coding Engine
Processors
Consoles
- 2 Pixel fillrate is calculated as the number of ROPs multiplied by the base core clock speed.
- 3 Texture fillrate is calculated as the number of TMUs multiplied by the base core clock speed.
Device | CPU | GPU | Memory | Special features | |||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Cores | Frequency | L2 Cache | Cores (unified shaders : texture mapping units : render output units)[6] | Frequency | GFLOPS | Pixel Fillrate (GP/s)2 | Texture Fillrate (GT/s)3 | Amount | Bus Width (bit) | Bus Type | Bandwidth (GB/s) | ||
Sony PS4 | dual 4 core modules | 1.6 GHz(2.75 Ghz Turbo) | 2 x 2 MB | 1152:72:32 | 800 MHz | 1840 | 25.6 | 57.6 | 8 GB | 256 | GDDR5 | 176 | 8 ACEs in the GPU and additional modules |
Microsoft Xbox One | dual 4 core modules | 1.75 GHz | 2 x 2 MB | 768:48:16 | 853 MHz | 1310 | 13.6 | 40.9 | 8 GB | 256 | DDR3 | 68 | 2 ACEs in the GPU and 32MB ESRAM 204 GB/s |
Desktop
SoCs using Socket AM1:
Model | CPU | GPU | TDP | Memory | Socket | ||||
---|---|---|---|---|---|---|---|---|---|
Cores | Frequency | L2 Cache | Model | Cores (unified shaders : texture mapping units : render output units) |
Frequency | ||||
Athlon 5350[7] | 4 | 2.05 GHz | 2 MB | Radeon R3 | 128:24:8[8] | 600 MHz | 25 W | DDR3-1600 | AM1 |
Athlon 5150 | 1.6 GHz | ||||||||
Sempron 3850 | 1.3 GHz | 450 MHz | |||||||
Sempron 2650 | 2 | 1.45 GHz | 1 MB | 400 MHz | DDR3-1333 |
Desktop/Mobile
Target segment |
Model | CPU | GPU | TDP | Memory | Turbo Core | ||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|
Cores | Frequency | Max. Turbo | L2 Cache | Model | Config. | Frequency | Turbo | |||||
Notebooks /Mini-PCs[9] |
A6-5200 | 4 | 2.0 GHz | — | 2 MB | HD 8400 | 128:16:4[10] | 600 MHz | — | 25 W | DDR3L-1600 | No |
A4-5100 | 1.55 GHz | HD 8330 | 500 MHz | 15 W | ||||||||
A4-5000 | 1.5 GHz | HD 8330 | 500 MHz | |||||||||
Notebooks | E2-3000 | 2 | 1.65 GHz | 1 MB | HD 8280 | 450 MHz | ||||||
E1-2500 | 1.4 GHz | HD 8240 | 400 MHz | DDR3L-1333 | ||||||||
E1-2100 | 1.0 GHz | HD 8210 | 300 MHz | 9 W | ||||||||
Tablets | A6-1450 | 4 | 1.4 GHz | 2 MB | HD 8250 | 400 MHz | 8 W | DDR3L-1066 | Yes | |||
A4-1350[11] | — | HD 8210 | — | DDR3-1066 | No | |||||||
A4-1250 | 2 | 1 MB | HD 8210 | DDR3L-1333 | ||||||||
A4-1200[12] | HD 8180 | 225 MHz | 3.9 W | DDR3L-1066 |
Server
Model | CPU | GPU | TDP | Memory | |||
---|---|---|---|---|---|---|---|
Cores | Frequency | L2 Cache | Cores | Frequency | |||
Opteron X2150 | 4 | 1.1–1.9 GHz | 2 MB | 128[13] | 266–600 MHz | 11–22 W | DDR3-1600 ECC |
Opteron X1150 | 1.0–2.0 GHz | — | 9–17 W |
^ CPU and GPU frequencies are adjustable in BIOS.[14]
Embedded
Model | CPU | GPU | TDP | Memory | ||||
---|---|---|---|---|---|---|---|---|
Cores | Frequency | L2 Cache | Model | Config. | Frequency | |||
GX-420CA | 4 | 2.0 GHz | 2 MB | HD 8400E | 128:16:4[citation needed] | 600 MHz | 25 W | DDR3-1600 ECC |
GX-416RA[15][16][17][18] | 1.6 GHz | — | 15 W | |||||
GX-415GA | 1.5 GHz | HD 8330E | 128:16:4[citation needed] | 500 MHz | ||||
GX-217GA | 2 | 1.65 GHz | 1 MB | HD 8280E | 450 MHz | |||
GX-210HA | 1.0 GHz | HD 8210E | 300 MHz | 9 W | DDR3-1333 ECC | |||
GX-210JA | HD 8180E | 225 MHz | 6 W | DDR3-1066 ECC |
References
- ^ a b "Software Optimization Guide for Family 16h Processors". AMD. Retrieved August 3, 2013.
- ^ "Xbox One vs. PS4: How the final hardware specs compare". ExtremeTech. November 22, 2013. Retrieved January 25, 2014.
- ^ "AMD releases 5 Kabinis and 3 Temashes". SemiAccurate. Retrieved July 16, 2013.
- ^ "AMD launches Opteron X-Series, Moving Jaguar into Servers". Bright Side Of News. Retrieved July 16, 2013.
- ^ a b c d e "Slide detailing improvements of Jaguar over Bobcat". AMD. Retrieved August 3, 2013.
- ^ "PlayStation 4 Xbox One Comparison Chart". Vgleaks. Retrieved 24 July 2014.
- ^ "AMD Introduces New Socketed AMD Sempron and AMD Athlon APU Products with AM1 Platform". AMD. Retrieved 9 April 2014.
- ^ AMD Radeon R3 5350 compare Nvidia GeForce GT 520 GPU
- ^ "AMD introduces its Mini-PC based Kabini". Tech News Pedia. Retrieved July 16, 2013.
- ^ Shimpi, Anand. "AMD's Jaguar Architecture: The CPU Powering Xbox One, PlayStation 4, Kabini & Temash". AnandTech. Retrieved August 3, 2013.
- ^ "AMD Expands Elite Mobility APU Line-Up with New Quad-Core Processor". Amd.com. 2013-06-29. Retrieved 2013-10-23.
- ^ "AMD Quanta A4-1200 APU Tablet Prototype". YouTube. 2013-06-29. Retrieved 2013-10-23.
- ^ "AMD's Opteron X-series targets Intel Atom for the microserver CPU market". Engadget. Retrieved July 16, 2013.
- ^ "Archived copy" (PDF). Archived from the original (PDF) on June 16, 2013. Retrieved July 15, 2013.
{{cite web}}
: Unknown parameter|deadurl=
ignored (|url-status=
suggested) (help)CS1 maint: archived copy as title (link) - ^ Shvets, Gennadiy. "AMD G-Series GX-416RA specifications". cpu-world.com. CPU-World. Retrieved 1 March 2015.
- ^ "AMD Embedded G-Series System-on-Chip (SOC)" (PDF). AMD. Retrieved 2013-11-10.
- ^ "Netboard A10". deciso.com. Deciso B.V. Retrieved 1 March 2015.
- ^ Schellevis, Jos. "Under the Hood: AMD G-Series SOC Delivers the Horsepower for Next Generation Firewalls". community.amd.com. Advanced Micro Devices, Inc. Retrieved 1 March 2015.
External links
- Software Optimization Guide for Family 16h Processors
- Jaguar AMD’s Next Generation Low Power x86 Core at Hot Chips 24
- Slides about the design of jaguar presented at ISSCC 2013
- Jaguar presentation (video) at ISSCC 2013
- Discussion initiated on RWT forums by Jeff Rupley, Chief Architect of the Jaguar core
- BKDG for Family 16h Models 00h-0Fh Processors
- Revision Guide for Family 16h Models 00h-0Fh Processors