Samsung Exynos 8895
HiSilicon Kirin 935
Comparision Samsung Exynos 8895 vs HiSilicon Kirin 935
Grade
Samsung Exynos 8895
HiSilicon Kirin 935
Interfaces and communications
4
6
Memory specification
3
2
Performance
10
10
Benchmark tests
3
1
Top specs and features
AnTuTu test score
Samsung Exynos 8895: 258759
HiSilicon Kirin 935: 138897
Memory frequency
Samsung Exynos 8895: 1866 MHz
HiSilicon Kirin 935: 1600 MHz
4G support
Samsung Exynos 8895: Available
HiSilicon Kirin 935: Available
Technological process
Samsung Exynos 8895: 10 nm
HiSilicon Kirin 935: 28 nm
GPU base clock
Samsung Exynos 8895: 900 MHz
HiSilicon Kirin 935: 680 MHz
Description
Samsung Exynos 8895 - 8 - core processor, clocked at 2314 GHz. HiSilicon Kirin 935 is equipped with 8 cores clocked at 2200 MHz. The maximum frequency of the first processor is 2.314 GHz. The second is capable of overclocking to 2.2 GHz.
Samsung Exynos 8895 consumes 5 Watt and HiSilicon Kirin 935 7 Watt.
As for the graphics core. Samsung Exynos 8895 is equipped with Mali-G71 MP20. The second uses Mali-T628 MP4. The first operates at a frequency of 900 MHz. HiSilicon Kirin 935 operates at 680 MHz.
Regarding processor memory. Samsung Exynos 8895 may support DDR4. The maximum memory capacity is 4 GB. And its throughput is 29 GB/s. HiSilicon Kirin 935 works with DDR3. The maximum amount of memory can be 8. At the same time, the throughput reaches 13 GB/s
Let's move on to performance testing in benchmarks. In the AnTuTu benchmark, Samsung Exynos 8895 scored 258759 points out of 988414 possible points. In the GeekBench 5 (Multi-Core) benchmark, it scored 1476 points out of a possible 16511 points. HiSilicon Kirin 935 in Antutu received 138897 points. And GeekBench 5 (Multi-Core) scored 739 points .
Results.
Why Samsung Exynos 8895 is better than HiSilicon Kirin 935
- AnTuTu test score 258759 против 138897 , more on 86%
- Memory frequency 1866 MHz против 1600 MHz, more on 17%
- Technological process 10 nm против 28 nm, less by -64%
- GPU base clock 900 MHz против 680 MHz, more on 32%
- Maximum processor frequency 2.314 GHz против 2.2 GHz, more on 5%
- L2 cache size 2 MB против 0.512 MB, more on 291%
- Memory Bandwidth 29 GB/s против 13 GB/s, more on 123%
Samsung Exynos 8895 vs HiSilicon Kirin 935: highlights
Samsung Exynos 8895
HiSilicon Kirin 935
Interfaces and communications
Vulcan version
The Vulkan version indicates supported features and functionality, and may include bug fixes and performance improvements introduced in recent API updates.
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1
Average: 1.1
1
Average: 1.1
Camera resolution (max)
28
Average: 69
32
Average: 69
4K video recording
120 FPS
Average: 44.3 FPS
30 FPS
Average: 44.3 FPS
H.265
Supports a video compression standard that provides more efficient use of bandwidth and higher video quality than previous standards such as H.264.
Available
Available
H.264
H.264 (or AVC) is a video coding standard that provides efficient, high quality video compression.
Available
Available
VP9
VP9 is an open video coding standard that provides efficient video compression with high image quality.
Available
There is no data
GPS
Available
Available
GLONASS
GLONASS is a global navigation and positioning system developed by Russia.
Available
Available
Beidou
A global navigation and positioning system developed by China.
Available
Available
eMMC version
standard flash memory format that is integrated directly into the SoC. Newer versions of eMMC provide faster data transfer speeds, faster app loading, and better overall device performance.
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2.1
Average: 2.7
2
Average: 2.7
WiFi Version
Indicates the supported version of the Wi-Fi wireless standard. Newer versions of Wi-Fi provide faster data transfer rates, more stable connections, and improved Wi-Fi network performance.
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5
Average: 5.2
5
Average: 5.2
4G support
LTE is located on a system on a chip (SoC). Built-in cellular-type LTE allows you to download much faster than older 3G technologies.
Available
Available
Intel® AES-NI Commands
AES is needed to speed up encryption and decryption.
Available
Available
Memory specification
Memory frequency
RAM may be faster to increase system performance.
1866 MHz
Average: 1701 MHz
1600 MHz
Average: 1701 MHz
Memory Bandwidth
This is the rate at which the device stores or reads information.
29 GB/s
Average: 24.1 GB/s
13 GB/s
Average: 24.1 GB/s
Max. Memory
The largest amount of RAM memory.
4 GB
Average: 17.1 GB
8 GB
Average: 17.1 GB
RAM version (DDR)
Indicates the type and speed of RAM used to temporarily store data and perform tasks on the device. Newer versions of DDR, such as DDR4 or DDR5, provide faster data transfer rates and better overall system performance.
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4
Average: 3.5
3
Average: 3.5
Performance
Number of Cores
The more cores, the more parallel tasks can be completed in a shorter time. This improves productivity and multitasking quickly, such as launching applications, performing calculations, and more.
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8
Average: 6.4
8
Average: 6.4
GPU
GPU that is responsible for graphics processing, including displaying images, videos, and performing complex graphics calculations. A more powerful and advanced GPU delivers better graphics performance, higher frame rates, and better visual realism.
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Mali-G71 MP20
Mali-T628 MP4
GPU architecture
The architecture of the GPU has an impact on the performance, power consumption, and functionality of the GPU. There are many different GPU architectures developed by different manufacturers such as NVIDIA, Qualcomm, ARM, and others.
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Bifrost
Midgard
GPU shaders
Refers to the parts of the GPU that are responsible for processing graphics and effects. The more shader units in the GPU, the higher the performance and graphics capabilities.
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320
Average: 122.4
64
Average: 122.4
CPU base frequency
The base frequency of a processor in mobile processors (SoCs) indicates its default operating frequency when the load on the processor does not require increased performance. The base frequency determines the base speed of the processor and affects the overall performance of the device.
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2314 MHz
Average: 922.4 MHz
2200 MHz
Average: 922.4 MHz
Data acquisition rate
Refers to the rate at which the processor can retrieve information from memory or other external data sources.
1000 MBits/s
Average: 812.6 MBits/s
300 MBits/s
Average: 812.6 MBits/s
Data download speed
Refers to the rate at which data is transferred between various system components such as memory, CPU, GPU, and others.
150 Mbit/s
Average: 176.3 Mbit/s
50 Mbit/s
Average: 176.3 Mbit/s
Hyper-threading
A technology that allows a single physical processor to execute multiple threads of tasks at the same time.
Not available
Not available
64-bit
The processor supports data and instruction processing with 64-bit width. This allows you to process more data and perform more complex calculations compared to 32-bit processors.
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Available
Available
Number of threads
The more threads, the higher the performance of the processor will be, and it will be able to perform several tasks at the same time.
8
Average: 5.7
8
Average: 5.7
Maximum processor frequency
When the processor's speed drops below its limit, it can jump to a higher clock speed to improve performance.
2.314 GHz
Average: 2.4 GHz
2.2 GHz
Average: 2.4 GHz
L2 cache size
An L2 cache with a large amount of scratchpad memory allows you to increase the speed of the processor and the overall performance of the system.
2 MB
Average: 1.6 MB
0.512 MB
Average: 1.6 MB
L1 cache size
A large amount of L1 memory accelerates results in the CPU and system performance settings
64 KB
Average: 158.4 KB
256 KB
Average: 158.4 KB
Multiplier Unlocked
Some processors have an unlocked multiplier, thanks to which they work faster and improve the quality in games and other applications.
Not available
Not available
FLOPS
The measurement of processing power of a processor is called FLOPS.
366 TFLOPS
Average: 262.9 TFLOPS
90 TFLOPS
Average: 262.9 TFLOPS
Benchmark tests
AnTuTu test score
AnTuTu is a popular mobile benchmark that is used to evaluate the performance and compare various aspects of mobile processors and systems on a chip (SoC).
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258759
Average: 324226.4
138897
Average: 324226.4
GeekBench 5 Single-Core score
The result of testing the performance of the processor in single-threaded mode using the GeekBench 5 benchmark. It measures the performance of a single processor core when performing various tasks.
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391
Average: 490.3
305
Average: 490.3
GeekBench 5 Multi-Core test score
GeekBench 5 Multi-Core is a benchmark that measures the multi-threaded performance of mobile processors and systems on a chip (SoC). The higher the value of this indicator, the more powerful the processor and the better it copes with the execution of several tasks at the same time.
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1476
Average: 1759.3
739
Average: 1759.3
FAQ
How many points does Samsung Exynos 8895 and HiSilicon Kirin 935 score in benchmarks?
In the Antutu benchmark, Samsung Exynos 8895 scored 258759 points. HiSilicon Kirin 935 scored 138897 points.
How many cores does the processor have?
Samsung Exynos 8895 has 8 cores. HiSilicon Kirin 935 has 8 cores.
Does the processor support NAVIC?
Samsung Exynos 8895 There is no data.
How many transistors are there in processors?
Samsung Exynos 8895 has 3000 million transistors. HiSilicon Kirin 935 has 1000 million transistors.
What GPU is installed on Samsung Exynos 8895 and HiSilicon Kirin 935?
Samsung Exynos 8895 uses Mali-G71 MP20. Processor HiSilicon Kirin 935 has graphics core Mali-T628 MP4 installed.
How fast are the processors?
Samsung Exynos 8895 is clocked at 2314 MHz. HiSilicon Kirin 935 operates at 2200 MHz.
What kind of RAM is supported?
Samsung Exynos 8895 supports DDR4. HiSilicon Kirin 935 supports DDR3.
What is the maximum frequency of processors?
Samsung Exynos 8895 has a maximum frequency of 2.314 Hz. The maximum frequency for HiSilicon Kirin 935 reaches 2.2 GHz.
How much energy do they consume?
The power consumption of Samsung Exynos 8895 can be up to 5 Watts. HiSilicon Kirin 935 has up to 5 Watts.
