CPU comparison with benchmarks
CPU comparison
Intel Core i7-7700K vs. AMD Ryzen 5 3600? We examine which of these two CPUs is superior in this comparison. We contrast the benchmark results with technical data.
The AMD Ryzen 5 3600 features six cores, twelve threads, and a maximum clock speed of 4.20 GHz. Two memory channels each handle up to 128 GB of RAM. In Q3 of 2019, AMD Ryzen 5 3600 became available. If you have bought AMD Ryzen 5 3600 and you are looking to find the best processor for AMD Ryzen 5 3600 then don’t worry there are many processors in the market that are highly compatible with it and provide an amazing experience.
The maximum clock speed of the Intel Core i7-7700K, which has 4 cores and 8 threads, is 4.50 GHz. Up to 64 GB of memory in 2 memory channels is supported by the CPU. In Q1 2017, the Intel Core i7-7700K was made available.
| AMD Ryzen 5 | Family | Intel Core i7 |
| AMD Ryzen 3000 | CPU group | Intel Core i 7000 |
| 3 | Generation | 7 |
| Matisse (Zen 2) | Architecture | Kaby Lake S |
| Desktop / Server | Segment | Desktop / Server |
| AMD Ryzen 5 2600 | Predecessor | Intel Core i7-6700K |
| — | Successor | Intel Core i7-8700K |
CPU Cores and Base Frequency
You can see here whether the AMD Ryzen 5 3600 or Intel Core i7-7700K can be overclocked in addition to the amount of CPU cores and threads. Additionally, you may discover here the processor’s single-core and multi-core clock frequencies. The processor’s speed is significantly influenced by the number of CPU cores.
If you are looking for a little upgrade then you must read a deadly comparison of Ryzen 5 3600 Vs 5600x that will help you decide whether you should give this little upgrade or not.
| 6 | Cores | 4 |
| 12 | Threads | 8 |
| normal | Core architecture | normal |
| Yes | Hyperthreading | Yes |
| Yes | Overclocking ? | Yes |
| 3.60 GHz | Frequency | 4.20 GHz |
| 4.20 GHz | Turbo Frequency (1 Core) | 4.50 GHz |
| 4.00 GHz | Turbo Frequency (All Cores) | 4.40 GHz |
Internal Graphics
Integrated graphics, or i GPU for short, are a feature of the AMD Ryzen 5 3600 or Intel Core i7-7700K processors. The i GPU, which resides on the processor’s die, uses the system’s main memory as graphics memory. APU is another name for a processor with integrated graphics (Accelerated Processing Unit).
| no iGPU | GPU | Intel HD Graphics 630 |
| GPU frequency | 0.35 GHz | |
| GPU (Turbo) | 1.15 GHz | |
| GPU Generation | 9.5 | |
| Technology | 14 nm | |
| Max. displays | 3 | |
| Execution units | 24 | |
| Shader | 192 | |
| Max. GPU Memory | 64 GB | |
| DirectX Version | 12 |
Hardware codec support
When playing videos, a photo or video codec that is hardware accelerated can significantly increase a processor’s operating speed and prolong the battery life of laptops or smartphones.
| No | Codec h265 / HEVC (8 bit) | Decode / Encode |
| No | Codec h265 / HEVC (10 bit) | Decode / Encode |
| No | Codec h264 | Decode / Encode |
| No | Codec VP9 | Decode / Encode |
| No | Codec VP8 | Decode / Encode |
| No | Codec AV1 | No |
| No | Codec AVC | Decode / Encode |
| No | Codec VC-1 | Decode |
| No | Codec JPEG | Decode / Encode |
Memory & PCIe
The amount and type of memory have a significant impact on the processor’s speed. The memory bandwidth, which is measured in gigabytes per second, depends on a number of variables.
| DDR4-3200 | Memory | |
| 128 GB | Max. Memory | 64 GB |
| 2 | Memory channels | 2 |
| 51.2 GB/s | Bandwidth | — |
| Yes | ECC | No |
| L2 Cache | ||
| 32.00 MB | L3 Cache | 8.00 MB |
| 4.0 | PCIe version | 3.0 |
| 20 | PCIe lanes | 16 |
Thermal Management
The cooling system required to keep the processor cool enough is specified by the Thermal Design Power, or TDP. The TDP typically only provides a general notion of a CPU’s actual consumption.
| 65 W | TDP (PL1) | 91 W |
| — | TDP (PL2) | — |
| — | TDP up | — |
| — | TDP down | — |
| 95 °C | Tjunction max. | — |
Technical details
A list of the processors’ ISA extensions can be found here, along with details on the size of the level 2 and level 3 caches for the AMD Ryzen 5 3600 or Intel Core i7-7700K. We have provided you with documentation about the architecture, the manufacturing technology, and the release date.
| 7 nm | Technology | 14 nm |
| Chiplet | Chip design | Monolithic |
| x86-64 (64 bit) | Instruction set (ISA) | x86-64 (64 bit) |
| SSE4a, SSE4.1, SSE4.2, AVX2, FMA3 | ISA extensions | SSE4.1, SSE4.2, AVX2 |
| AM4 (LGA 1331) | Socket | LGA 1151 |
| AMD-V, SVM | Virtualization | VT-x, VT-x EPT, VT-d |
| Yes | AES-NI | Yes |
| Windows 10, Windows 11, Linux | Operating systems | Windows 10, Linux |
| Q3/2019 | Release date | Q1/2017 |
| 185 $ | Release price | 350 $ |
Cinebench R23 (Single-Core)
The sequel to Cinebench R20, Cinebench R23, is also built on the Cinema 4 Suite. A widely used piece of software to build 3D forms is Cinema 4. The number of cores or the capacity for hyperthreading are irrelevant in the single-core test because only one CPU core is used.
Cinebench R23 (Multi-Core)
The sequel to Cinebench R20, Cinebench R23, is also built on the Cinema 4 Suite. A widely used piece of software to build 3D forms is Cinema 4. All CPU cores are used in the multi-core test, which greatly benefits from hyperthreading.
Cinebench R20 (Single-Core)
The replacement for Cinebench R15, Cinebench R20, is built on the Cinema 4 Suite. A widely used piece of software to build 3D forms is Cinema 4. The number of cores or the capacity for hyperthreading are irrelevant in the single-core test because only one CPU core is used.
Cinebench R20 (Multi-Core)
The replacement for Cinebench R15, Cinebench R20, is built on the Cinema 4 Suite. A widely used piece of software to build 3D forms is Cinema 4. All CPU cores are used in the multi-core test, which greatly benefits from hyperthreading.
Geekbench 5, 64bit (Single-Core)
Cross-platform benchmark Geekbench 5 makes heavy use of the computer’s memory. A quick memory will greatly accelerate the outcome. The number of cores or the capacity for hyperthreading are irrelevant in the single-core test because only one CPU core is used.
Geekbench 5, 64bit (Multi-Core)
Cross-platform benchmark Geekbench 5 makes heavy use of the computer’s memory. A quick memory will greatly accelerate the outcome. All CPU cores are used in the multi-core test, which greatly benefits from hyperthreading.
CPU-Z Benchmark 17 (Single-Core)
The CPU-Z benchmark calculates the time it takes a system to finish all benchmark calculations in order to assess a processor’s performance. The score increases as the benchmark is achieved more quickly.
CPU-Z Benchmark 17 (Multi-Core)
By tracking how long it takes a system to finish all benchmark calculations, the CPU-Z test gauges a processor’s efficiency. The greater the score, the quicker the benchmark must be accomplished.
iGPU – FP32 Performance (Single-precision GFLOPS)
Theoretical processing power measured in GFLOPS for the processor’s inbuilt graphics unit with simple accuracy (32 bit). The iGPU’s floating point processing speed is measured in GFLOPS, or gigaflops per second.
Blender 3.1 Benchmark
The scenes “monster,” “junkshop,” and “classroom” are produced as part of the Blender Benchmark 3.1, and the system’s rendering time is recorded. In our benchmark, the CPU, not the graphics card, is tested. In March 2022, Blender 3.1 was unveiled as a stand-alone version.
Estimated results for Pass Mark CPU Mark
The CPU-monkey benchmark has been applied to several of the CPUs listed below. The majority of CPUs, however, have not been put to the test, and the results have been calculated using a CPU-monkey exclusive secret method. As a result, they are not supported by Pass Mark Software Pty Ltd. and do not accurately reflect the official Pass mark CPU mark values.
Blender 2.81 (bmw27)
Free 3D graphics programmed called Blender may be used to render (create) 3D bodies, which can then be animated and given textures. The Blender benchmark builds predefined scenarios and counts the number of seconds needed to complete each scene. The better, the less time is needed. The benchmark scenario that we choose is bmw27.
V-Ray CPU-Render Benchmark
V-Ray is a 3D rendering programme for designers and artists from the company Chaos. Contrary to many other render engines, V-Ray has the ability to perform simultaneous CPU and GPU-based hybrid rendering.
The CPU test (CPU Render Mode) we utilised, however, solely makes use of the system’s processor. The V-Ray benchmark heavily relies on the working memory used. We use the quickest RAM standard permitted by the vendor for our benchmarks (without overclocking).
V-Ray is a widely used software because of its high level of compatibility, which includes Autodesk 3ds Max, Maya, Cinema 4D, SketchUp, Unreal Engine, and Blender. V-Ray, for instance, may be used to produce photos that are so realistic that the average person cannot tell them apart from regular photographs.
Monero Hashrate kH/s
Since November 2019, the crypto currency Monero has started utilising the RandomX algorithm. Only a processor (CPU) or graphics card can be used to calculate this PoW (proof of work) algorithm effectively (GPU). Up until November 2019, Monero employed the CryptoNight algorithm, although ASICs could calculate it. High CPU core counts, cache, and quick memory connections across as many memory channels as possible are all advantages of RandomX. tested using the HiveOS operating system and XMRig v6.x.
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Cinebench R15 (Single-Core)
The successor to Cinebench 11.5 is Cinebench R15, which is similarly built on the Cinema 4 Suite. A widely used piece of software to build 3D forms is Cinema 4. The number of cores or the capacity for hyperthreading are irrelevant in the single-core test because only one CPU core is used.
Cinebench R15 (Multi-Core)
The successor to Cinebench 11.5 is Cinebench R15, which is similarly built on the Cinema 4 Suite. A widely used piece of software to build 3D forms is Cinema 4. All CPU cores are used in the multi-core test, which greatly benefits from hyperthreading.
Geekbench 3, 64bit (Single-Core)
Cross-platform benchmark Geekbench 3 makes heavy use of the computer’s memory. A quick memory will greatly accelerate the outcome. The number of cores or the capacity for hyperthreading are irrelevant in the single-core test because only one CPU core is used.
Geekbench 3, 64bit (Multi-Core)
Cross-platform benchmark Geekbench 3 makes heavy use of the computer’s memory. A quick memory will greatly accelerate the outcome. All CPU cores are used in the multi-core test, which greatly benefits from hyperthreading.
Cinebench R11.5, 64bit (Single-Core)
The Cinema 4D Suite, a programmed widely used to create forms and other 3D objects, is the foundation for Cinebench 11.5’s functionality. The number of cores or the capacity for hyperthreading are irrelevant in the single-core test because only one CPU core is used.
Cinebench R11.5, 64bit (Multi-Core)
The Cinema 4D Suite, a programmed widely used to create forms and other 3D objects, is the foundation for Cinebench 11.5’s functionality. All CPU cores are used in the multi-core test, which greatly benefits from hyperthreading.
Cinebench R11.5, 64bit (iGPU, OpenGL)
The Cinema 4D Suite, a programmed widely used to create forms and other 3D objects, is the foundation for Cinebench 11.5’s functionality. The internal graphic unit of the CPU is used by the iGPU test to carry out OpenGL operations.
