Core i5-3330 vs Xeon E5-2680 v2
Description
Both models i5-3330 and E5-2680 v2 are based on Ivy Bridge architecture.
"Ivy Bridge is the last Intel microarchitecture for which there is official driver support for Windows XP . It is made under 22 nm Tri-Gate transistor (""3D"") technology and is basically a Sandy Bridge shrink. It has PCI Express 3.0 support and RdRand instruction for security tasks."
Using the multithread performance as a reference, the i5-3330 gets a score of 104.8 k points while the E5-2680 v2 gets 551.1 k points.
Summarizing, the E5-2680 v2 is 5.3 times faster than the i5-3330 . To get a proper comparison between both models, take a look to the data shown below.
"Ivy Bridge is the last Intel microarchitecture for which there is official driver support for Windows XP . It is made under 22 nm Tri-Gate transistor (""3D"") technology and is basically a Sandy Bridge shrink. It has PCI Express 3.0 support and RdRand instruction for security tasks."
Using the multithread performance as a reference, the i5-3330 gets a score of 104.8 k points while the E5-2680 v2 gets 551.1 k points.
Summarizing, the E5-2680 v2 is 5.3 times faster than the i5-3330 . To get a proper comparison between both models, take a look to the data shown below.
Specs
CPUID
306a9
306e4
Core
Ivy Bridge
Ivy Bridge-EP
Base frecuency
3 GHz
2.8 GHz
Boost frecuency
3.2 GHz
3.6 GHz
Socket
LGA 1155
LGA 2011
Cores/Threads
4/4
10 /20
TDP
77 W
115 W
Cache L1 (d+i)
32+32 kB
10x32+10x32 kB
Cache L2
256 kB
10x256 kB
Cache L3
6144 kB
25600 kB
Date
September 2012
September 2013
Mean monothread perf.
29.84k points
28.23k points
Mean multithread perf.
104.78k points
551.1k points
AVX optimized benchmark
The benchmark in mode II (AVX) is optimized to used 256 bits registers beside the first version of the Advanced Vector Extensions (AVX). The first AVX compatible CPU was released in 2011.
Monothread
i5-3330
E5-2680 v2
Test#1 (Integers)
10.85k
10.55k (x0.97)
Test#2 (FP)
10.47k
10.02k (x0.96)
Test#3 (Generic, ZIP)
4.21k
3.99k (x0.95)
Test#1 (Memory)
4.31k
3.66k (x0.85)
TOTAL
29.84k
28.23k (x0.95)
Multithread
i5-3330
E5-2680 v2
Test#1 (Integers)
41.77k
215.04k (x5.15)
Test#2 (FP)
40.2k
230.43k (x5.73)
Test#3 (Generic, ZIP)
16.11k
96.87k (x6.01)
Test#1 (Memory)
6.7k
8.76k (x1.31)
TOTAL
104.78k
551.1k (x5.26)
Performance/W
i5-3330
E5-2680 v2
Test#1 (Integers)
542 points/W
1870 points/W
Test#2 (FP)
522 points/W
2004 points/W
Test#3 (Generic, ZIP)
209 points/W
842 points/W
Test#1 (Memory)
87 points/W
76 points/W
TOTAL
1361 points/W
4792 points/W
Performance/GHz
i5-3330
E5-2680 v2
Test#1 (Integers)
3390 points/GHz
2931 points/GHz
Test#2 (FP)
3272 points/GHz
2784 points/GHz
Test#3 (Generic, ZIP)
1316 points/GHz
1109 points/GHz
Test#1 (Memory)
1347 points/GHz
1017 points/GHz
TOTAL
9325 points/GHz
7841 points/GHz
Monothread performance graph
Monothread performance graphics gives the performance vs time. They are useful to measure the time it takes to the CPU to reach the maximum performance.
Usually, CPU's performance will be steady during these tests but if it has a slow frequency strategy, the first samples will show a lower score.
Usually, CPU's performance will be steady during these tests but if it has a slow frequency strategy, the first samples will show a lower score.
Test#1 (Integers) [points vs time]
Test#2 (FP) [points vs time]
Test#3 (Generic, ZIP) [points vs time]
Test#1 (Memory) [points vs time]
Multithread performance graph
Multithread graphs measure the performance against a heavy load during certain time.
If CPU's TDP doesn't limit the frequency and the machine is properly cooled, performance should remain steady vs time. Otherwise, the performance score will oscillate or decrease over time.
If CPU's TDP doesn't limit the frequency and the machine is properly cooled, performance should remain steady vs time. Otherwise, the performance score will oscillate or decrease over time.
Test#1 (Integers) [points vs time]
Test#2 (FP) [points vs time]
Test#3 (Generic, ZIP) [points vs time]
Test#1 (Memory) [points vs time]
Hardlimit Benchmark Central - Ver. 3.11.4