AMD C-30

8 Reasons why AMD C-30 is better

than the average

1.Appreciably lower TDP
9Wvs 67W (the average)
vs 3W (best: Intel Atom Z670)
The thermal design power (TDP) is the maximum amount of power the cooling system needs to dissipate. A lower TDP typically means that it consumes less power.
2.Appreciably more L2 cache per core
0.5MB/corevs 0.4MB/core (the average)
vs 2.5MB/core (best: Intel Core i5-4200Y)
More data can be stored in the L2 cache for access by each core of the CPU.
3.A little bit newer version of DirectX
11vs 11 (the average)
vs 12 (best: AMD A10-7870K)
DirectX is used in games, with newer versions supporting better graphics.
4.Clearly newer version of OpenGL
4.1vs 3.7 (the average)
vs 4.5 (best: AMD A10-7860K)
OpenGL is used in games, with newer versions supporting better graphics.
5.A tad newer version of OpenCL
1.2vs 1.2 (the average)
vs 2 (best: Intel Xeon E3-1275 v5)
Some applications use OpenCL to utilise the power of the graphics processing unit (GPU) for non-graphical computing. Newer versions introduce more functionality and better performance.
6.A shade higher maximum operating temperature
90°Cvs 88°C (the average)
vs 105°C (best: Intel Core i7-3940XM)
If the CPU exceeds the maximum operating temperature then problems such as random resets can occur.
19mmvs 37mm (the average)
vs 6mm (best: Apple A5 APL7498)
19mmvs 36mm (the average)
vs 6mm (best: Apple A5 APL7498)
AMD C-30
AMD C-30 specs
AMD C-30 features
AMD C-30 pros and cons
AMD C-30 advantages
AMD C-30 disadvantages