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The ''Jaguar'' core has support for the following instruction sets and instructions: [[MMX (instruction set)|MMX]], [[Streaming SIMD Extensions|SSE]], [[SSE2]], [[SSE3]], [[SSSE3]], [[SSE4a]], [[SSE4.1]], [[SSE4.2]], [[Advanced Vector Extensions|AVX]], [[F16C]], CLMUL, [[AES instruction set|AES]], BMI1, MOVBE (Move Big-Endian instruction), XSAVE/XSAVEOPT, [[Bit Manipulation Instruction Sets|ABM]] (POPCNT/LZCNT), and [[AMD-V]].<ref name="opti guide" />
The ''Jaguar'' core has support for the following instruction sets and instructions: [[MMX (instruction set)|MMX]], [[Streaming SIMD Extensions|SSE]], [[SSE2]], [[SSE3]], [[SSSE3]], [[SSE4a]], [[SSE4.1]], [[SSE4.2]], [[Advanced Vector Extensions|AVX]], [[F16C]], CLMUL, [[AES instruction set|AES]], BMI1, MOVBE (Move Big-Endian instruction), XSAVE/XSAVEOPT, [[Bit Manipulation Instruction Sets|ABM]] (POPCNT/LZCNT), and [[AMD-V]].<ref name="opti guide" />


== Improvements over [[Bobcat (microarchitecture)|''Bobcat'']] ==
=== Improvements over [[Bobcat (microarchitecture)|''Bobcat'']] ===
* Over 10% increase in clock frequency<ref name="Slides">{{cite web
* Over 10% increase in clock frequency<ref name="Slides">{{cite web
| title = Slide detailing improvements of Jaguar over Bobcat
| title = Slide detailing improvements of Jaguar over Bobcat
Line 62: Line 62:
* Integrated [[Fusion controller hub]] (FCH)
* Integrated [[Fusion controller hub]] (FCH)
* [[Video Coding Engine]]
* [[Video Coding Engine]]

== Features and ASICs ==
{{AMD APU features}}


== Processors ==
== Processors ==

Revision as of 18:10, 26 January 2020

Jaguar - Family 16h
General information
LaunchedMid-2013
Discontinuedpresent
Common manufacturer
Cache
L1 cache64 KB per core[1]
L2 cache1 MB to 2 MB shared
Architecture and classification
Technology node28 nm
Instruction setAMD64 (x86-64)
Physical specifications
Sockets
Products, models, variants
Core names
  • Kabini
  • Temash
  • Kyoto
  • G-series
  • Athlon, Sempron, A4, A6, & E4
History
PredecessorBobcat - Family 14h
SuccessorPuma - Family 16h (2nd-gen)

The AMD Jaguar Family 16h is a low-power microarchitecture designed by AMD. It is 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 two DDR3L DIMMs in one channel at frequencies up to 1600 MHz[3]
  • Server processors support two 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

Features and ASICs

The following table shows features of AMD's processors with 3D graphics, including APUs (see also: List of AMD processors with 3D graphics).

[ VisualEditor ]
Platform High, standard and low power Low and ultra-low power
Codename Server Basic Toronto
Micro Kyoto
Desktop Performance Raphael Phoenix
Mainstream Llano Trinity Richland Kaveri Kaveri Refresh (Godavari) Carrizo Bristol Ridge Raven Ridge Picasso Renoir Cezanne
Entry
Basic Kabini Dalí
Mobile Performance Renoir Cezanne Rembrandt Dragon Range
Mainstream Llano Trinity Richland Kaveri Carrizo Bristol Ridge Raven Ridge Picasso Renoir
Lucienne 		Cezanne
Barceló 		Phoenix
Entry Dalí Mendocino
Basic Desna, Ontario, Zacate Kabini, Temash Beema, Mullins Carrizo-L Stoney Ridge Pollock
Embedded Trinity Bald Eagle Merlin Falcon,
Brown Falcon 		Great Horned Owl Grey Hawk Ontario, Zacate Kabini Steppe Eagle, Crowned Eagle,
LX-Family 		Prairie Falcon Banded Kestrel River Hawk
Released Aug 2011 Oct 2012 Jun 2013 Jan 2014 2015 Jun 2015 Jun 2016 Oct 2017 Jan 2019 Mar 2020 Jan 2021 Jan 2022 Sep 2022 Jan 2023 Jan 2011 May 2013 Apr 2014 May 2015 Feb 2016 Apr 2019 Jul 2020 Jun 2022 Nov 2022
CPU microarchitecture K10 Piledriver Steamroller Excavator "Excavator+"[6] Zen Zen+ Zen 2 Zen 3 Zen 3+ Zen 4 Bobcat Jaguar Puma Puma+[7] "Excavator+" Zen Zen+ "Zen 2+"
ISA x86-64 v1 x86-64 v2 x86-64 v3 x86-64 v4 x86-64 v1 x86-64 v2 x86-64 v3
Socket Desktop Performance AM5
Mainstream AM4
Entry FM1 FM2 FM2+ FM2+[a], AM4 AM4
Basic AM1 FP5
Other FS1 FS1+, FP2 FP3 FP4 FP5 FP6 FP7 FL1 FP7
FP7r2
FP8 		? FT1 FT3 FT3b FP4 FP5 FT5 FP5 FT6
PCI Express version 2.0 3.0 4.0 5.0 4.0 2.0 3.0
CXL
Fab. (nm) GF 32SHP
(HKMG SOI) 		GF 28SHP
(HKMG bulk) 		GF 14LPP
(FinFET bulk) 		GF 12LP
(FinFET bulk) 		TSMC N7
(FinFET bulk) 		TSMC N6
(FinFET bulk) 		CCD: TSMC N5
(FinFET bulk)
cIOD: TSMC N6
(FinFET bulk) 		TSMC 4nm
(FinFET bulk) 		TSMC N40
(bulk) 		TSMC N28
(HKMG bulk) 		GF 28SHP
(HKMG bulk) 		GF 14LPP
(FinFET bulk) 		GF 12LP
(FinFET bulk) 		TSMC N6
(FinFET bulk)
Die area (mm2) 228 246 245 245 250 210[8] 156 180 210 CCD: (2x) 70
cIOD: 122 		178 75 (+ 28 FCH) 107 ? 125 149 ~100
Min TDP (W) 35 17 12 10 15 105 35 4.5 4 3.95 10 6 12 8
Max APU TDP (W) 100 95 65 45 170 54 18 25 6 54 15
Max stock APU base clock (GHz) 3 3.8 4.1 4.1 3.7 3.8 3.6 3.7 3.8 4.0 3.3 4.7 4.3 1.75 2.2 2 2.2 3.2 2.6 1.2 3.35 2.8
Max APUs per node[b] 1 1
Max core dies per CPU 1 2 1 1
Max CCX per core die 1 2 1 1
Max cores per CCX 4 8 2 4 2 4
Max CPU[c] cores per APU 4 8 16 8 2 4 2 4
Max threads per CPU core 1 2 1 2
Integer pipeline structure 3+3 2+2 4+2 4+2+1 1+3+3+1+2 1+1+1+1 2+2 4+2 4+2+1
i386, i486, i586, CMOV, NOPL, i686, PAE, NX bit, CMPXCHG16B, AMD-V, RVI, ABM, and 64-bit LAHF/SAHF Yes Yes
IOMMU[d] v2 v1 v2
BMI1, AES-NI, CLMUL, and F16C Yes Yes
MOVBE Yes
AVIC, BMI2, RDRAND, and MWAITX/MONITORX Yes
SME[e], TSME[e], ADX, SHA, RDSEED, SMAP, SMEP, XSAVEC, XSAVES, XRSTORS, CLFLUSHOPT, CLZERO, and PTE Coalescing Yes Yes
GMET, WBNOINVD, CLWB, QOS, PQE-BW, RDPID, RDPRU, and MCOMMIT Yes Yes
MPK, VAES Yes
SGX
FPUs per core 1 0.5 1 1 0.5 1
Pipes per FPU 2 2
FPU pipe width 128-bit 256-bit 80-bit 128-bit 256-bit
CPU instruction set SIMD level SSE4a[f] AVX AVX2 AVX-512 SSSE3 AVX AVX2
3DNow! 3DNow!+
PREFETCH/PREFETCHW Yes Yes
GFNI Yes
AMX
FMA4, LWP, TBM, and XOP Yes Yes
FMA3 Yes Yes
AMD XDNA Yes
L1 data cache per core (KiB) 64 16 32 32
L1 data cache associativity (ways) 2 4 8 8
L1 instruction caches per core 1 0.5 1 1 0.5 1
Max APU total L1 instruction cache (KiB) 256 128 192 256 512 256 64 128 96 128
L1 instruction cache associativity (ways) 2 3 4 8 2 3 4 8
L2 caches per core 1 0.5 1 1 0.5 1
Max APU total L2 cache (MiB) 4 2 4 16 1 2 1 2
L2 cache associativity (ways) 16 8 16 8
Max on--die L3 cache per CCX (MiB) 4 16 32 4
Max 3D V-Cache per CCD (MiB) 64
Max total in-CCD L3 cache per APU (MiB) 4 8 16 64 4
Max. total 3D V-Cache per APU (MiB) 64
Max. board L3 cache per APU (MiB)
Max total L3 cache per APU (MiB) 4 8 16 128 4
APU L3 cache associativity (ways) 16 16
L3 cache scheme Victim Victim
Max. L4 cache
Max stock DRAM support DDR3-1866 DDR3-2133 DDR3-2133, DDR4-2400 DDR4-2400 DDR4-2933 DDR4-3200, LPDDR4-4266 DDR5-4800, LPDDR5-6400 DDR5-5200 DDR5-5600, LPDDR5x-7500 DDR3L-1333 DDR3L-1600 DDR3L-1866 DDR3-1866, DDR4-2400 DDR4-2400 DDR4-1600 DDR4-3200 LPDDR5-5500
Max DRAM channels per APU 2 1 2 1 2
Max stock DRAM bandwidth (GB/s) per APU 29.866 34.132 38.400 46.932 68.256 102.400 83.200 120.000 10.666 12.800 14.933 19.200 38.400 12.800 51.200 88.000
GPU microarchitecture TeraScale 2 (VLIW5) TeraScale 3 (VLIW4) GCN 2nd gen GCN 3rd gen GCN 5th gen[9] RDNA 2 RDNA 3 TeraScale 2 (VLIW5) GCN 2nd gen GCN 3rd gen[9] GCN 5th gen RDNA 2
GPU instruction set TeraScale instruction set GCN instruction set RDNA instruction set TeraScale instruction set GCN instruction set RDNA instruction set
Max stock GPU base clock (MHz) 600 800 844 866 1108 1250 1400 2100 2400 400 538 600 ? 847 900 1200 600 1300 1900
Max stock GPU base GFLOPS[g] 480 614.4 648.1 886.7 1134.5 1760 1971.2 2150.4 3686.4 102.4 86 ? ? ? 345.6 460.8 230.4 1331.2 486.4
3D engine[h] Up to 400:20:8 Up to 384:24:6 Up to 512:32:8 Up to 704:44:16[10] Up to 512:32:8 768:48:8 128:8:4 80:8:4 128:8:4 Up to 192:12:8 Up to 192:12:4 192:12:4 Up to 512:?:? 128:?:?
IOMMUv1 IOMMUv2 IOMMUv1 ? IOMMUv2
Video decoder UVD 3.0 UVD 4.2 UVD 6.0 VCN 1.0[11] VCN 2.1[12] VCN 2.2[12] VCN 3.1 ? UVD 3.0 UVD 4.0 UVD 4.2 UVD 6.0 UVD 6.3 VCN 1.0 VCN 3.1
Video encoder VCE 1.0 VCE 2.0 VCE 3.1 VCE 2.0 VCE 3.1
AMD Fluid Motion No Yes No No Yes No
GPU power saving PowerPlay PowerTune PowerPlay PowerTune[13]
TrueAudio Yes[14] ? Yes
FreeSync 1
2 		1
2
HDCP[i] ? 1.4 2.2 2.3 ? 1.4 2.2 2.3
PlayReady[i] 3.0 not yet 3.0 not yet
Supported displays[j] 2–3 2–4 3 3 (desktop)
4 (mobile, embedded)		 4 2 3 4 4
/drm/radeon[k][16][17] Yes Yes
/drm/amdgpu[k][18] Yes[19] Yes[19]
  1. ^ For FM2+ Excavator models: A8-7680, A6-7480 & Athlon X4 845.
  2. ^ A PC would be one node.
  3. ^ An APU combines a CPU and a GPU. Both have cores.
  4. ^ Requires firmware support.
  5. ^ a b Requires firmware support.
  6. ^ No SSE4. No SSSE3.
  7. ^ Single-precision performance is calculated from the base (or boost) core clock speed based on a FMA operation.
  8. ^ Unified shaders : texture mapping units : render output units
  9. ^ a b To play protected video content, it also requires card, operating system, driver, and application support. A compatible HDCP display is also needed for this. HDCP is mandatory for the output of certain audio formats, placing additional constraints on the multimedia setup.
  10. ^ To feed more than two displays, the additional panels must have native DisplayPort support.[15] Alternatively active DisplayPort-to-DVI/HDMI/VGA adapters can be employed.
  11. ^ a b DRM (Direct Rendering Manager) is a component of the Linux kernel. Support in this table refers to the most current version.

Processors

See also: List of AMD Accelerated Processing Unit microprocessors and List of AMD mobile microprocessors

Consoles

Chip
(device) 		Release date Fab Die area (mm2) CPU GPU Memory Storage API support Special features
Archi-
tecture 		Cores Clock (GHz) L2 cache Archi-
tecture 		Core config[a] Clock (MHz) GFLOPS[b] Pixel fillrate (GP/s)[c] Texture fillrate (GT/s)[d] Other Size Bus type & width Band-
width (GB/s) 		Audio Other
Liverpool
(PS4) 		Nov 2013 28 nm 348 Jaguar 8 cores 1.6 2× 2 MB GCN 2 1152:72:32
18 CU 		800 1843 25.6 57.6 8 ACEs 8 GB GDDR5
256-bit 		176 3DBD/DVD
1× 2.5" SATA hard drive
Easily replaceable hard drive
USB 3.0 		OpenGL 4.2, GNM, GNMX and PSSL Dolby Atmos (BD)
S/PDIF 		PS VR
PS4 additional modules
HDR10 (except discs)[e]
CEC
Optional IR sensor
Durango
(Xbox One) 		Nov 2013 363 1.75 768:48:16
12 CU 		853 1310 13.6 40.9 2 ACEs 32 MB ESRAM[f] 204 3DBD/DVD/CD
1× 2.5" SATA hard drive
USB 3.0 		Direct3D 11.2 and 12 Fully Dolby Atmos, DTS:X, and Windows Sonic
S/PDIF 		Xbox One additional modules
FreeSync (1)
HDMI 1.4 through
IR sensor and IR out port
Kensington lock
8 GB DDR3
256-bit 		68
Edmonton
(Xbox One S) [20] 		Jun 2016 16 nm 240 914 1404 14.6 43.9 2 ACEs 32 MB ESRAM 219 4KBD/3DBD/DVD/CD[g]
1× 2.5" SATA hard drive
USB 3.0 		Fully Dolby Atmos, DTS:X, and Windows Sonic
S/PDIF 		Xbox One S additional modules
Fully HDR10
Dolby Vision (streaming)
FreeSync (1&2)
HDMI 1.4 through
IR sensor and IR out port
Kensington lock
8 GB DDR3
256-bit 		68
(PS4 Slim) Sep 2016 208 1.6 1152:72:32
18 CU 		800 1843 25.6 57.6 8 ACEs 8 GB GDDR5
256-bit 		176 3DBD/DVD
1× 2.5" SATA hard drive
Easily replaceable hard drive
USB 3.0 		OpenGL 4.2, GNM, GNMX and PSSL Dolby Atmos (BD) PS VR
PS4 Slim additional modules
HDR10 (except discs)
CEC
Optional IR sensor
Neo
(PS4 Pro) [21][22][23] 		Nov 2016 325 2.13 GCN 4
(Polaris) [24] 		2304:144:32
36 CU 		911 4198 58.3 131.2 4 ACEs and 2 HWS
Double-rate FP16[h]
checkerboard rendering 		8 GB[25] GDDR5
256-bit 		218 3DBD/DVD
1× 2.5" SATA hard drive
Easily replaceable hard drive
USB 3.0 		OpenGL 4.2 (4.5), GNM, GNMX and PSSL Dolby Atmos (BD)
S/PDIF 		PS VR
PS4 Pro additional modules
HDR10 (except discs)
Up to 4K@60 Hz
CEC
Optional IR sensor
1 GB DDR3[i] ?
Scorpio
(Xbox One X) [26][27][28] 		Nov 2017 359 Customized
Jaguar 		2.3 2560:160:32
40 CU 		1172 6001 37.5 187.5 4 ACEs and 2 HWS 12 GB GDDR5
384-bit 		326 4KBD/3DBD/DVD/CD
1× 2.5" SATA hard drive
USB 3.0 		Direct3D 11.2 and 12 Fully Dolby Atmos, DTS:X, and Windows Sonic
S/PDIF 		Xbox One X additional modules
Fully HDR10
Dolby Vision (streaming)
FreeSync (1&2)
Up to 4K@60 Hz
HDMI 1.4b through
IR sensor and IR out port
Fenghuang
(Subor Z+) [29][30][31] 		cancelled [32] 14 nm [33] 397 Zen 4 cores
8 threads 		3.0 GCN 5 1536:96:32
24 CU 		1300 3994 41.6 124.8 Double-rate FP16 8 GB GDDR5
256-bit 		154 1× 2.5" SATA SSD
1× 2.5" SATA hard drive
Easily replaceable drives
USB 3.0 		Vulkan 1.1, Direct3D 12.1 S/PDIF Subor Z Plus additional modules
Windows 10 Enterprise LTSC
Oberon
(PS5) [34] 		Nov 2020 7 nm 308 Zen 2 8 cores
16 threads 		3.5 (variable) 8 MB RDNA 2 2304:144:64
36 CU 		2233 (variable) 10290 (variable) 142.9 321.6 Double-rate FP16
Real-time ray tracing
Primitive shaders
Custom 3D audio blocks 		16 GB GDDR6
256-bit 		448 4KBD
Custom 5.5 GB/s PCIe 4.0 x4 NVMe SSD
PCIe 4.0 M.2 slot
Easily replaceable M.2 SSD
USB (except PS5 games) 		Vulkan 1.2 PS5 TEMPEST 3D AudioTech PS VR
Dedicated DMA controller and I/O coprocessors
Custom coherency engines and cache scrubbers
Custom decompression block
HDR
Up to 4K@120 Hz
Up to 8K@30 Hz
Anaconda
(Xbox Series X) 		Nov 2020 360 3.6
(3.8 w/o SMT) 		4 MB 3328:208:64
52 CU 		1825 12147 116.8 379.6 Double-rate FP16
Real-time ray tracing
Mesh shaders
Variable rate shading
ANN acceleration 		10 GB GDDR6
320-bit 		560 4KBD
Custom 2.4 GB/s NVMe SSD
Custom expansion card
USB 3.1 (except XSX games) 		DirectX 12 Ultimate Custom spatial audio block
MS Project Acoustics
Fully Dolby Atmos, DTS:X, and Windows Sonic 		Custom decompression block
HDR
VRR
Up to 4K@120 Hz
Up to 8K@30 Hz
CEC
6 GB GDDR6
192-bit[j] 		336
Lockhart
(Xbox Series S) 		197 3.4
(3.6 w/o SMT) 		1280:80:32
20 CU 		1565 4006 50.1 125.2 8 GB GDDR6
128-bit 		224
2 GB GDDR6
32-bit 		56
Van Gogh
"Aerith"
(Steam Deck)[35] 		Dec 2021 163 4 cores
8 threads 		2.4-3.5 2 MB 512:32:16
8 CU 		1000-1600 1000-1600 16-25.6 32-51.2 Double-rate FP16
Real-time ray tracing
Variable rate shading
 16 GB LPDDR5
128-bit 		88 64 GB eMMC (PCIe Gen 2 × 1)
256 GB NVMe SSD (PCIe Gen 3 × 4)
512 GB NVMe SSD (PCIe Gen 3 × 4)
microSD card slot 		DirectX 9-12 Ultimate, OpenGL 4.6, Vulkan 1.2
Van Gogh
"Sephiroth"(Steam Deck OLED) 		Nov 2023 6 nm 131 102 256 GB NVMe SSD (PCIe Gen 3 × 4)
512 GB NVMe SSD (PCIe Gen 3 × 4)
1 TB NVMe SSD (PCIe Gen 3 × 4)
microSD card slot
  1. ^ Unified shaders : Texture mapping units : Render output units
  2. ^ Precision performance is calculated from the base (or boost) core clock speed based on a FMA operation.
  3. ^ Pixel fillrate is calculated as the number of ROPs multiplied by the base (or boost) core clock speed.
  4. ^ Texture fillrate is calculated as the number of TMUs multiplied by the base (or boost) core clock speed.
  5. ^ UHD BD is the only video disc format supporting HDR.
  6. ^ Cache
  7. ^ "Digital" version does not have an optical drive.
  8. ^ Feature preview of Rapid Packed Math, introduced in GCN 5.
  9. ^ Swap
  10. ^ A plain 320-bit 20 GB version could be made by just replacing four 1 GB GDDR6 chips by 2 GB ones.

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 5370 4 2.2 GHz 2 MB Radeon R3 128:8:4[36] 600 MHz 25 W DDR3-1600 AM1
Athlon 5350[37] 2.05 GHz
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[38] 		A6-5200 4 2.0 GHz 2 MB HD 8400 128:8:4[39] 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 09 W
Tablets A6-1450 4 1.4 GHz 2 MB HD 8250 400 MHz 08 W DDR3L-1066 Yes
A4-1350[40] HD 8210 DDR3-1066 No
A4-1250 2 1 MB HD 8210 DDR3L-1333
A4-1200[41] HD 8180 225 MHz 03.9 W DDR3L-1066

Server

Opteron X1100-series "Kyoto" (28 nm)

Model Stepping CPU Memory
support		 TDP Released Part number Release
price (USD)
Cores Frequency Turbo L2 Cache Multi Vcore
X1150 B0 4 2.0 GHz 2 MB DDR3 17 W May 2013 OX1150IPJ44HM $64

Opteron X2100-series "Kyoto" (28 nm)

Model Stepping CPU GPU Memory
support		 TDP Released Part number Release
price (USD)
Cores Frequency Turbo L2 Cache Multi Vcore Model Config Frequency Turbo
X2150 B0 4 1.9 GHz 2 MB HD 8400 800 MHz DDR3 22 W May 2013 OX2150IAJ44HM $99
X2170 4 2.4 GHz 2 MB HD 8400 800 MHz DDR3 25 W September 2016 OX2170IXJ44JB

Embedded

Model CPU GPU TDP Memory
Cores Frequency L2 Cache Model Config. Frequency
GX-420CA 4 2.0 GHz 2 MB HD 8400E 128:8:4[citation needed] 600 MHz 25 W DDR3-1600 ECC
GX-416RA[42][43][44][45] 1.6 GHz 15 W
GX-415GA 1.5 GHz HD 8330E 128:8:4[citation needed] 500 MHz
GX-412TC[46] 1.0 GHz 6 W DDR3-1333 ECC
GX-411GA 1.1 GHz HD 8210E 128:8:4[citation needed] 300 MHz 15 W DDR3-1600 ECC
GX-217GA 2 1.65 GHz 1 MB HD 8280E 450 MHz
GX-210HA 1.0 GHz HD 8210E 300 MHz 09 W DDR3-1333 ECC
GX-210JA HD 8180E 225 MHz 06 W DDR3-1066 ECC

Jaguar derivative and successor

In 2017 a derivative of the Jaguar microarchitecture was announced in the APU of Microsoft's Xbox One X (Project Scorpio) revision to the Xbox One.[47] The Project Scorpio APU is described as a 'customized' derivative of the Jaguar microarchitecture, utilizing eight cores clocked at 2.3 GHz.[48][49]

The Puma successor to Jaguar was released in 2014 and targeting entry level notebooks and tablets.[50]

References

  1. ^ a b "Software Optimization Guide for Family 16h Processors". AMD. Retrieved August 3, 2013.
  2. ^ "Xbox One vs. PS4: How the final hardware specs compare". ExtremeTech. November 22, 2013. Retrieved January 25, 2014.
  3. ^ "AMD releases 5 Kabinis and 3 Temashes". SemiAccurate. Retrieved July 16, 2013.
  4. ^ "AMD launches Opteron X-Series, Moving Jaguar into Servers". Bright Side Of News. Retrieved July 16, 2013.
  5. ^ a b c d e "Slide detailing improvements of Jaguar over Bobcat". AMD. Retrieved August 3, 2013.
  6. ^ "AMD Announces the 7th Generation APU: Excavator mk2 in Bristol Ridge and Stoney Ridge for Notebooks". 31 May 2016. Retrieved 3 January 2020.
  7. ^ "AMD Mobile "Carrizo" Family of APUs Designed to Deliver Significant Leap in Performance, Energy Efficiency in 2015" (Press release). 20 November 2014. Retrieved 16 February 2015.
  8. ^ "The Mobile CPU Comparison Guide Rev. 13.0 Page 5 : AMD Mobile CPU Full List". TechARP.com. Retrieved 13 December 2017.
  9. ^ a b "AMD VEGA10 and VEGA11 GPUs spotted in OpenCL driver". VideoCardz.com. Retrieved 6 June 2017.
  10. ^ Cutress, Ian (1 February 2018). "Zen Cores and Vega: Ryzen APUs for AM4 – AMD Tech Day at CES: 2018 Roadmap Revealed, with Ryzen APUs, Zen+ on 12nm, Vega on 7nm". Anandtech. Retrieved 7 February 2018.
  11. ^ Larabel, Michael (17 November 2017). "Radeon VCN Encode Support Lands in Mesa 17.4 Git". Phoronix. Retrieved 20 November 2017.
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