Xeon Bronze 3206R vs Core i5-1035G1

Description

The 3206R is based on Cascade Lake architecture while the i5-1035G1 is based on Ice Lake.

Using the multithread performance as a reference, the 3206R gets a score of 216 k points while the i5-1035G1 gets 171.6 k points.

Summarizing, the 3206R is 1.3 times faster than the i5-1035G1. To get a proper comparison between both models, take a look to the data shown below.

Specs

3206R

i5-1035G1

CPUID

50657

706e5

Core

Cascade Lake-SP

Ice Lake-U

Architecture

Cascade Lake

Ice Lake

Base frecuency

1.9 GHz

1 GHz

Boost frecuency

1.9 GHz

3.6 GHz

Socket

LGA 3647-0

BGA 1526

Cores/Threads

8/8

4/8

TDP

85 W

15 W

Cache L1 (d+i)

8x32+8x32 kB

4x32+4x48 kB

Cache L2

8x1024 kB

4x512 kB

Cache L3

11264 kB

6144 kB

Date

February 2020

August 2019

Mean monothread perf.

31.52k points

55.37k points

Mean multithread perf.

216.02k points

171.65k points

Non-optimized benchmark

The benchmark in Mode 0 (FPU) measures cpu performance with non-optimized software. It uses the basic µinstructions from the i386 architecture with the i387 floating point unit. This mode is compatible with all CPUs so it's practical to compare very different CPUs

Monothread

3206R

i5-1035G1

Test#1 (Integers)

1.97k

3.88k (x1.97)

Test#2 (FP)

8.15k

14.98k (x1.84)

Test#3 (Generic, ZIP)

2.37k

9.7k (x4.1)

Test#1 (Memory)

4.84k

8.6k (x1.78)

TOTAL

17.32k

37.15k (x2.15)

Multithread

3206R

i5-1035G1

Test#1 (Integers)

15.73k

14.61k (x0.93)

Test#2 (FP)

64.78k

54.9k (x0.85)

Test#3 (Generic, ZIP)

18.06k

27.58k (x1.53)

Test#1 (Memory)

5.21k

5.04k (x0.97)

TOTAL

103.77k

102.13k (x0.98)

AVX2 optimized benchmark

The benchmark in mode III (AVX2), like AVX1, is optimized to used 256 bits registers beside the second version of the Advanced Vector Extensions (AVX). The first AVX2 compatible CPU was released in 2013.

Monothread

3206R

i5-1035G1

Test#1 (Integers)

12.92k

21.5k (x1.66)

Test#2 (FP)

10.97k

17.71k (x1.61)

Test#3 (Generic, ZIP)

2.54k

7.92k (x3.12)

Test#1 (Memory)

5.09k

8.24k (x1.62)

TOTAL

31.52k

55.37k (x1.76)

Multithread

3206R

i5-1035G1

Test#1 (Integers)

103.33k

73.03k (x0.71)

Test#2 (FP)

87.67k

68.19k (x0.78)

Test#3 (Generic, ZIP)

20.1k

24.89k (x1.24)

Test#1 (Memory)

4.91k

5.54k (x1.13)

TOTAL

216.02k

171.65k (x0.79)

Performance/W

3206R

i5-1035G1

Test#1 (Integers)

1216 points/W

4869 points/W

Test#2 (FP)

1031 points/W

4546 points/W

Test#3 (Generic, ZIP)

237 points/W

1660 points/W

Test#1 (Memory)

58 points/W

369 points/W

TOTAL

2541 points/W

11443 points/W

Performance/GHz

3206R

i5-1035G1

Test#1 (Integers)

6801 points/GHz

5972 points/GHz

Test#2 (FP)

5774 points/GHz

4919 points/GHz

Test#3 (Generic, ZIP)

1334 points/GHz

2201 points/GHz

Test#1 (Memory)

2678 points/GHz

2290 points/GHz

TOTAL

16588 points/GHz

15381 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.

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.

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