CPU comparison with benchmarks |
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CPU lineage |
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Samsung Exynos 4415 or Samsung Exynos 4415 – 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 HiSilicon Kirin 658 features 8 processor cores and has the capability to manage 8 threads concurrently. It was released in Q2/2016 and belongs to the 4 generation of the HiSilicon Kirin series. |
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| Group | HiSilicon Kirin 650 | |
| Family | HiSilicon Kirin | |
| -- | Segment | Mobile |
| -- | Generation | 4 |
| Samsung Exynos 4415 | Name | HiSilicon Kirin 658 |
CPU Cores and Base Frequency |
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The HiSilicon Kirin 658 has 8 CPU cores and can calculate 8 threads in parallel.
The clock frequency of the A-Core is 2.35 GHz. The number of CPU cores greatly affects the speed of the processor and is an important performance indicator. Processors with hybrid (big.LITTLE) architecture strike a balance between performance and power efficiency, making them ideal for mobile devices. |
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| No | Overclocking | No |
| None | None | 4x Cortex-A53 |
| No | Hyperthreading | No |
| -- | Threads | 8 |
| -- | CPU Cores | 8 |
| -- | Core architecture | hybrid (big.LITTLE) |
| None | None | 4x Cortex-A53 |
| None | None | 1.7 GHz |
| None | None | 2.35 GHz |
Internal Graphics |
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The Samsung Exynos 4415 does not have integrated graphics.
The HiSilicon Kirin 658 has integrated graphics, called iGPU for short. Specifically, the HiSilicon Kirin 658 uses the ARM Mali-T830 MP2, which has 32 texture shaders and 2 execution units. The iGPU uses the system's main memory as graphics memory and sits on the processor's die. |
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| -- | Direct X | 11 |
| -- | Generation | Midgard 4 |
| -- | GPU (Turbo) | -- |
| -- | Release date | Q4/2015 |
| -- | Technology | 28 nm |
| GPU name | ARM Mali-T830 MP2 | |
| -- | Execution units | 2 |
| -- | GPU frequency | 0.9 GHz |
| -- | Max. displays | -- |
| 0 bytes | Max. GPU Memory | 0 bytes |
| -- | Shaders | 32 |
Artificial Intelligence and Machine Learning |
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| -- | AI hardware | -- |
| -- | AI specifications | -- |
Hardware codec support |
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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.
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| -- | VP9 | No |
| -- | VP8 | Decode / Encode |
| -- | h265 / HEVC (10 bit) | Decode |
| -- | h264 | Decode / Encode |
| -- | AV1 | No |
| -- | AVC | No |
| -- | h265 / HEVC (8 bit) | Decode / Encode |
| -- | JPEG | Decode / Encode |
| -- | VC-1 | No |
Memory & PCIe |
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| pci | PCIe | pci |
| -- | Memory channels | 2 |
| No | AES-NI | No |
| No | ECC | No |
| 0 bytes | Max. Memory | 0 bytes |
| -- | Bandwidth | -- |
| Memory type | LPDDR3-933 | |
Thermal Management |
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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.
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| -- | Tjunction max | -- |
Technical details |
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A smaller manufacturing process indicates a more contemporary and energy-efficient CPU.
A substantial cache can significantly enhance the processor's performance, particularly in scenarios like gaming. The HiSilicon Kirin 658 is manufactured using a 16 nm process. |
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| -- | Chip design | Chiplet |
| -- | Release price | -- |
| ISA extensions | ||
| Instruction set (ISA) | ARMv8-A64 (64 bit) | |
| -- | Release date | Q2/2016 |
| Virtualization | None | |
| -- | Part Number | -- |
| -- | Architecture | Cortex-A53 / Cortex-A53 |
| -- | Technology | 16 nm |
| Technical data sheet | Documents | Technical data sheet |
| 0 bytes | L3-Cache | 0 bytes |
| 0 bytes | L2-Cache | 0 bytes |
| Socket | ||
| Operating systems | Android | |
Geekbench 5, 64bit (Multi-Core)
Geekbench 5, 64bit (Single-Core)
iGPU - FP32 Performance (Single-precision GFLOPS)
