AMD A6-7050B vs AMD E2-3300M

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CPU comparison with benchmarks

-VS-

CPU lineage

AMD A6-7050B or AMD A6-7050B – which processor offers superior performance? In this comparison, we examine disparities and assess which of these two CPUs outperforms the other. We delve into technical specifications and benchmark outcomes.
The AMD A6-7050B features 2 processor cores and has the capability to manage 2 threads concurrently.
It was released in Q2/2014 and belongs to the 5 generation of the AMD A series.
To use the AMD A6-7050B, you'll need a motherboard with a FM2+ socket.
The AMD E2-3300M features 2 processor cores and has the capability to manage 2 threads concurrently.
It was released in Q3/2011 and belongs to the 3 generation of the AMD E series.
To use the AMD E2-3300M, you'll need a motherboard with a FS1 socket.
5 Generation 3
AMD A6-7050B Name AMD E2-3300M
Mobile Segment Mobile
AMD A Family AMD E
AMD A6-7000 Group AMD E2-3000
 
 

CPU Cores and Base Frequency

The AMD A6-7050B has 2 CPU cores and can calculate 2 threads in parallel.
The clock frequency of the AMD A6-7050B is 2.2 GHz
and turbo frequency for one core is 3.0 GHz.
The AMD E2-3300M has 2 CPU cores and can calculate 2 threads in parallel.
The clock frequency of the AMD E2-3300M is 1.8 GHz
and turbo frequency for one core is 2.2 GHz.
normal Core architecture normal
No Overclocking Yes
2 CPU Cores 2
2 Threads 2
2x Cores 2x
3.0 GHz Turbo Frequency (1 core) 2.2 GHz
2.2 GHz Frequency 1.8 GHz
3.0 GHz Turbo Frequency (all cores) 2.2 GHz
No Hyperthreading No
 
 

Internal Graphics

The AMD A6-7050B has integrated graphics, called iGPU for short.
Specifically, the AMD A6-7050B uses the AMD Radeon R4 (Kaveri), which has 192 texture shaders
and 3 execution units.
The iGPU uses the system's main memory as graphics memory and sits on the processor's die.
The AMD E2-3300M has integrated graphics, called iGPU for short.
Specifically, the AMD E2-3300M uses the AMD Radeon HD 6480G, which has 240 texture shaders
6 Generation 3
12 Direct X 11
28 nm Technology 32 nm
3 Execution units 3
192 Shaders 240
0.53 GHz GPU (Turbo) --
2.0 GB Max. GPU Memory 1.0 GB
Q2/2014 Release date Q2/2011
0.49 GHz GPU frequency 0.44 GHz
AMD Radeon R4 (Kaveri) GPU name AMD Radeon HD 6480G
-- Max. displays --
 
 

Artificial Intelligence and Machine Learning

-- AI hardware --
-- AI specifications --
 
 

Hardware codec support

A photo or video codec that is accelerated in hardware can greatly accelerate the working speed of a processor and extend the battery life of notebooks or smartphones when playing videos.
No VP9 No
No AV1 No
Decode VC-1 Decode
Decode / Encode JPEG Decode / Encode
No h265 / HEVC (8 bit) No
No h265 / HEVC (10 bit) No
No VP8 No
Decode AVC Decode
Decode h264 Decode
 
 

Memory & PCIe

Yes AES-NI Yes
pci PCIe pci
DDR3-1600 Memory type DDR3-1333
0 bytes Max. Memory 0 bytes
No ECC No
2 Memory channels 1
-- Bandwidth --
 
 

Thermal Management

The processor has a thermal design power (TDP) of 17 W watts.
TDP indicates the cooling solution needed to effectively manage the processor's heat. It generally provides an approximate indication of the actual power consumption of the CPU itself.
The processor has a thermal design power (TDP) of 35 W watts.
17 W TDP (PL1 / PBP) 35 W
-- Tjunction max --
 
 

Technical details

The AMD A6-7050B is manufactured using a 28 nm process.
A smaller manufacturing process indicates a more contemporary and energy-efficient CPU.
In total, this processor boasts a generous 1.0 MB cache.
A substantial cache can significantly enhance the processor's performance, particularly in scenarios like gaming.
The AMD E2-3300M is manufactured using a 28 nm process.
SSE4a, SSE4.1, SSE4.2, AVX, FMA3, FMA4 ISA extensions SSE3, SSE4a
0 bytes L2-Cache 0 bytes
FM2+ Socket FS1
AMD-V Virtualization AMD-V
-- Part Number --
Kaveri (Steamroller) Architecture Llano (K10)
28 nm Technology 28 nm
x86-64 (64 bit) Instruction set (ISA) x86-64 (64 bit)
-- Release price --
Technical data sheet Documents Technical data sheet
1.0 MB L3-Cache 1.0 MB
Q2/2014 Release date Q3/2011
Operating systems
-- Chip design --