AMD A10-8700P vs Intel Core i3-7100: What is the difference?
44points
AMD A10-8700P
50points
Intel Core i3-7100
Comparison winner
vs
64 facts in comparison
AMD A10-8700P
Intel Core i3-7100
Why is AMD A10-8700P better than Intel Core i3-7100?
- 450MHz faster GPU clock speed?
800MHzvs350MHz - 1.5MB bigger L2 cache?
2MBvs0.5MB - 36W lower TDP?
15Wvs51W - 192KB bigger L1 cache?
320KBvs128KB - 0.25MB/core more L2 cache per core?
0.5MB/corevs0.25MB/core - Has FMA4?
Why is Intel Core i3-7100 better than AMD A10-8700P?
- 8.33% faster CPU speed?
2 x 3.9GHzvs4 x 1.8GHz - 267MHz higher ram speed?
2400MHzvs2133MHz - 10°C higher maximum operating temperature?
100°Cvs90°C - 14nm smaller semiconductor size?
14nmvs28nm - 1. 68x higher PassMark result?
5967vs3555 - 4.3GB/s more memory bandwidth?
38.4GB/svs34.1GB/s - 1.77x higher PassMark result (single)?
2231vs1259 - Uses multithreading?
Which are the most popular comparisons?
AMD A10-8700P
vs
Intel Core i5-7600
Intel Core i3-7100
vs
Intel Pentium Silver N5000
AMD A10-8700P
vs
Intel Core i5-7200U
Intel Core i3-7100
vs
Intel Pentium Gold G5400
AMD A10-8700P
vs
Intel Core i5-4300U
Intel Core i3-7100
vs
AMD Ryzen 5 1400
AMD A10-8700P
vs
Intel Core i7-6500U
Intel Core i3-7100
vs
Intel Core i5-3330
AMD A10-8700P
vs
AMD A10-9700
Intel Core i3-7100
vs
Intel Core i5-4200U
AMD A10-8700P
vs
Intel Core i5-6200U
Intel Core i3-7100
vs
AMD Ryzen 3 1200
AMD A10-8700P
vs
Intel Core i5-4440
Intel Core i3-7100
vs
Intel Core i7-3770
AMD A10-8700P
vs
Intel Core i3-8100
Intel Core i3-7100
vs
AMD Ryzen 3 1300X
AMD A10-8700P
vs
Intel Core i7-7567U
Intel Core i3-7100
vs
Intel Core i5-6200U
Intel Core i3-7100
vs
Intel Pentium G4560
Price comparison
User reviews
Overall Rating
AMD A10-8700P
1 User reviews
AMD A10-8700P
9. 0/10
1 User reviews
Intel Core i3-7100
1 User reviews
Intel Core i3-7100
10.0/10
1 User reviews
Features
Value for money
10.0/10
1 votes
7.0/10
1 votes
Gaming
10.0/10
1 votes
9.0/10
1 votes
Performance
9.0/10
1 votes
10.0/10
1 votes
Reliability
7.0/10
1 votes
10.0/10
1 votes
Energy efficiency
8.0/10
1 votes
7.0/10
1 votes
Performance
1.CPU speed
4 x 1.8GHz
2 x 3.9GHz
The CPU speed indicates how many processing cycles per second can be executed by a CPU, considering all of its cores (processing units). It is calculated by adding the clock rates of each core or, in the case of multi-core processors employing different microarchitectures, of each group of cores.
2.CPU threads
More threads result in faster performance and better multitasking.
3.turbo clock speed
3.2GHz
Unknown. Help us by suggesting a value. (Intel Core i3-7100)
When the CPU is running below its limitations, it can boost to a higher clock speed in order to give increased performance.
4.Has an unlocked multiplier
✖AMD A10-8700P
✖Intel Core i3-7100
Some processors come with an unlocked multiplier which makes them easy to overclock, allowing you to gain increased performance in games and other apps.
5.L2 cache
A larger L2 cache results in faster CPU and system-wide performance.
6.L3 cache
Unknown. Help us by suggesting a value. (AMD A10-8700P)
A larger L3 cache results in faster CPU and system-wide performance.
7. L1 cache
A larger L1 cache results in faster CPU and system-wide performance.
8.L2 core
0.5MB/core
0.25MB/core
More data can be stored in the L2 cache for access by each core of the CPU.
9.L3 core
Unknown. Help us by suggesting a value. (AMD A10-8700P)
1.5MB/core
More data can be stored in the L3 cache for access by each core of the CPU.
Memory
1.RAM speed
2133MHz
2400MHz
It can support faster memory, which will give quicker system performance.
2.maximum memory bandwidth
34.1GB/s
38.4GB/s
This is the maximum rate that data can be read from or stored into memory.
3.DDR memory version
Unknown. Help us by suggesting a value. (AMD A10-8700P)
DDR (Double Data Rate) memory is the most common type of RAM. Newer versions of DDR memory support higher maximum speeds and are more energy-efficient.
4.memory channels
More memory channels increases the speed of data transfer between the memory and the CPU.
5.maximum memory amount
Unknown. Help us by suggesting a value. (AMD A10-8700P)
The maximum amount of memory (RAM) supported.
6.bus transfer rate
Unknown. Help us by suggesting a value. (AMD A10-8700P)
The bus is responsible for transferring data between different components of a computer or device.
7.Supports ECC memory
✖AMD A10-8700P
✖Intel Core i3-7100
Error-correcting code memory can detect and correct data corruption. It is used when is it essential to avoid corruption, such as scientific computing or when running a server.
8.eMMC version
Unknown. Help us by suggesting a value. (AMD A10-8700P)
Unknown. Help us by suggesting a value. (Intel Core i3-7100)
A higher version of eMMC allows faster memory interfaces, having a positive effect on the performance of a device. For example, when transferring files from your computer to the internal storage over USB.
9.bus speed
Unknown. Help us by suggesting a value. (AMD A10-8700P)
Unknown. Help us by suggesting a value. (Intel Core i3-7100)
The bus is responsible for transferring data between different components of a computer or device.
Benchmarks
1.PassMark result
This benchmark measures the performance of the CPU using multiple threads.
2.PassMark result (single)
This benchmark measures the performance of the CPU using a single thread.
3.Geekbench 5 result (multi)
Unknown. Help us by suggesting a value. (AMD A10-8700P)
Unknown. Help us by suggesting a value. (Intel Core i3-7100)
Geekbench 5 is a cross-platform benchmark that measures a processor’s multi-core performance. (Source: Primate Labs, 2022)
4.Cinebench R20 (multi) result
Unknown. Help us by suggesting a value. (AMD A10-8700P)
Unknown. Help us by suggesting a value. (Intel Core i3-7100)
Cinebench R20 is a benchmark tool that measures a CPU’s multi-core performance by rendering a 3D scene.
5.Cinebench R20 (single) result
Unknown. Help us by suggesting a value. (AMD A10-8700P)
Unknown. Help us by suggesting a value. (Intel Core i3-7100)
Cinebench R20 is a benchmark tool that measures a CPU’s single-core performance by rendering a 3D scene.
6.Geekbench 5 result (single)
Unknown. Help us by suggesting a value. (AMD A10-8700P)
Unknown. Help us by suggesting a value. (Intel Core i3-7100)
Geekbench 5 is a cross-platform benchmark that measures a processor’s single-core performance. (Source: Primate Labs, 2022)
7. Blender (bmw27) result
Unknown. Help us by suggesting a value. (AMD A10-8700P)
Unknown. Help us by suggesting a value. (Intel Core i3-7100)
The Blender (bmw27) benchmark measures the performance of a processor by rendering a 3D scene. More powerful processors can render the scene in less time.
8.Blender (classroom) result
Unknown. Help us by suggesting a value. (AMD A10-8700P)
Unknown. Help us by suggesting a value. (Intel Core i3-7100)
The Blender (classroom) benchmark measures the performance of a processor by rendering a 3D scene. More powerful processors can render the scene in less time.
9.performance per watt
Unknown. Help us by suggesting a value. (AMD A10-8700P)
Unknown. Help us by suggesting a value. (Intel Core i3-7100)
This means the CPU is more efficient, giving a greater amount of performance for each watt of power used.
Features
1. uses multithreading
✖AMD A10-8700P
✔Intel Core i3-7100
Multithreading technology (such as Intel’s Hyperthreading or AMD’s Simultaneous Multithreading) provides increased performance by splitting each of the processor’s physical cores into virtual cores, also known as threads. This way, each core can run two instruction streams at once.
2.Has AES
✔AMD A10-8700P
✔Intel Core i3-7100
AES is used to speed up encryption and decryption.
3.Has AVX
✔AMD A10-8700P
✔Intel Core i3-7100
AVX is used to help speed up calculations in multimedia, scientific and financial apps, as well as improving Linux RAID software performance.
4.SSE version
SSE is used to speed up multimedia tasks such as editing an image or adjusting audio volume. Each new version contains new instructions and improvements.
5.Has F16C
✔AMD A10-8700P
✔Intel Core i3-7100
F16C is used to speed up tasks such as adjusting the contrast of an image or adjusting volume.
6.bits executed at a time
Unknown. Help us by suggesting a value. (AMD A10-8700P)
Unknown. Help us by suggesting a value. (Intel Core i3-7100)
NEON provides acceleration for media processing, such as listening to MP3s.
7.Has MMX
✔AMD A10-8700P
✔Intel Core i3-7100
MMX is used to speed up tasks such as adjusting the contrast of an image or adjusting volume.
8.Has TrustZone
✖AMD A10-8700P
✖Intel Core i3-7100
A technology integrated into the processor to secure the device for use with features such as mobile payments and streaming video using digital rights management (DRM).
9.front-end width
Unknown. Help us by suggesting a value. (AMD A10-8700P)
Unknown. Help us by suggesting a value. (Intel Core i3-7100)
The CPU can decode more instructions per clock (IPC), meaning that the CPU performs better
Price comparison
Cancel
Which are the best CPUs?
AMD A10-5800K vs Intel Core i3-4130: What is the difference?
47points
AMD A10-5800K
39points
Intel Core i3-4130
Comparison winner
vs
64 facts in comparison
AMD A10-5800K
Intel Core i3-4130
Why is AMD A10-5800K better than Intel Core i3-4130?
- 2. 24x faster CPU speed?
4 x 3.8GHzvs2 x 3.4GHz - 266MHz higher ram speed?
1866MHzvs1600MHz - 450MHz faster GPU clock speed?
800MHzvs350MHz - 3.5MB bigger L2 cache?
4MBvs0.5MB - 64KB bigger L1 cache?
192KBvs128KB - Has an unlocked multiplier?
- 0.75MB/core more L2 cache per core?
1MB/corevs0.25MB/core - 1 more displays supported?
4vs3
Why is Intel Core i3-4130 better than AMD A10-5800K?
- 10nm smaller semiconductor size?
22nmvs32nm - 5.64% higher PassMark result?
4965vs4700 - 46W lower TDP?
54Wvs100W - 1 newer version of PCI Express (PCIe)?
3vs2 - 4.6GB/s more memory bandwidth?
25.6GB/svs21GB/s - 36.91% higher PassMark result (single)?
2018vs1474 - 97million more transistors?
1400 millionvs1303 million - Supports ECC memory?
Which are the most popular comparisons?
AMD A10-5800K
vs
Intel Core i5-3450
Intel Core i3-4130
vs
Intel Pentium G3220
AMD A10-5800K
vs
AMD A8-7600
Intel Core i3-4130
vs
Intel Core i5-3330
AMD A10-5800K
vs
Intel Core i5-3470
Intel Core i3-4130
vs
Intel Core i5-2400
AMD A10-5800K
vs
Intel Core i7-3517U
Intel Core i3-4130
vs
Intel Core i5-3470
AMD A10-5800K
vs
Intel Core i5-3330
Intel Core i3-4130
vs
Intel Celeron N3060
AMD A10-5800K
vs
Intel Core i5-2400
Intel Core i3-4130
vs
AMD A10-8780P
AMD A10-5800K
vs
AMD A10-7850K
Intel Core i3-4130
vs
Intel Core i3-4130T
AMD A10-5800K
vs
AMD A4-5300
Intel Core i3-4130
vs
Intel Core i3-1115G4
AMD A10-5800K
vs
AMD A6-5400K
Intel Core i3-4130
vs
Intel Core i3-3220
Price comparison
User reviews
Overall Rating
AMD A10-5800K
0 User reviews
AMD A10-5800K
0. 0/10
0 User reviews
Intel Core i3-4130
1 User reviews
Intel Core i3-4130
7.0/10
1 User reviews
Features
Value for money
No reviews yet
8.0/10
1 votes
Gaming
No reviews yet
6.0/10
1 votes
Performance
No reviews yet
8.0/10
1 votes
Reliability
No reviews yet
7.0/10
1 votes
Energy efficiency
No reviews yet
7.0/10
1 votes
Performance
1.CPU speed
4 x 3.8GHz
2 x 3.4GHz
The CPU speed indicates how many processing cycles per second can be executed by a CPU, considering all of its cores (processing units). It is calculated by adding the clock rates of each core or, in the case of multi-core processors employing different microarchitectures, of each group of cores.
2. CPU threads
More threads result in faster performance and better multitasking.
3.turbo clock speed
4.2GHz
Unknown. Help us by suggesting a value. (Intel Core i3-4130)
When the CPU is running below its limitations, it can boost to a higher clock speed in order to give increased performance.
4.Has an unlocked multiplier
✔AMD A10-5800K
✖Intel Core i3-4130
Some processors come with an unlocked multiplier which makes them easy to overclock, allowing you to gain increased performance in games and other apps.
5.L2 cache
A larger L2 cache results in faster CPU and system-wide performance.
6.L3 cache
Unknown. Help us by suggesting a value. (AMD A10-5800K)
A larger L3 cache results in faster CPU and system-wide performance.
7.L1 cache
A larger L1 cache results in faster CPU and system-wide performance.
8.L2 core
1MB/core
0.25MB/core
More data can be stored in the L2 cache for access by each core of the CPU.
9.L3 core
Unknown. Help us by suggesting a value. (AMD A10-5800K)
1.5MB/core
More data can be stored in the L3 cache for access by each core of the CPU.
Memory
1.RAM speed
1866MHz
1600MHz
It can support faster memory, which will give quicker system performance.
2.maximum memory bandwidth
21GB/s
25.6GB/s
This is the maximum rate that data can be read from or stored into memory.
3.DDR memory version
DDR (Double Data Rate) memory is the most common type of RAM. Newer versions of DDR memory support higher maximum speeds and are more energy-efficient.
4.memory channels
More memory channels increases the speed of data transfer between the memory and the CPU.
5.maximum memory amount
Unknown. Help us by suggesting a value. (AMD A10-5800K)
The maximum amount of memory (RAM) supported.
6.bus transfer rate
5.4GT/s
Unknown. Help us by suggesting a value. (Intel Core i3-4130)
The bus is responsible for transferring data between different components of a computer or device.
7.Supports ECC memory
✖AMD A10-5800K
✔Intel Core i3-4130
Error-correcting code memory can detect and correct data corruption. It is used when is it essential to avoid corruption, such as scientific computing or when running a server.
8.eMMC version
Unknown. Help us by suggesting a value. (AMD A10-5800K)
Unknown. Help us by suggesting a value. (Intel Core i3-4130)
A higher version of eMMC allows faster memory interfaces, having a positive effect on the performance of a device. For example, when transferring files from your computer to the internal storage over USB.
9.bus speed
Unknown. Help us by suggesting a value. (AMD A10-5800K)
Unknown. Help us by suggesting a value. (Intel Core i3-4130)
The bus is responsible for transferring data between different components of a computer or device.
Benchmarks
1.PassMark result
This benchmark measures the performance of the CPU using multiple threads.
2.PassMark result (single)
This benchmark measures the performance of the CPU using a single thread.
3.Geekbench 5 result (multi)
Unknown. Help us by suggesting a value. (AMD A10-5800K)
Unknown. Help us by suggesting a value. (Intel Core i3-4130)
Geekbench 5 is a cross-platform benchmark that measures a processor’s multi-core performance. (Source: Primate Labs, 2022)
4. Cinebench R20 (multi) result
Unknown. Help us by suggesting a value. (AMD A10-5800K)
Unknown. Help us by suggesting a value. (Intel Core i3-4130)
Cinebench R20 is a benchmark tool that measures a CPU’s multi-core performance by rendering a 3D scene.
5.Cinebench R20 (single) result
Unknown. Help us by suggesting a value. (AMD A10-5800K)
Unknown. Help us by suggesting a value. (Intel Core i3-4130)
Cinebench R20 is a benchmark tool that measures a CPU’s single-core performance by rendering a 3D scene.
6.Geekbench 5 result (single)
Unknown. Help us by suggesting a value. (AMD A10-5800K)
Unknown. Help us by suggesting a value. (Intel Core i3-4130)
Geekbench 5 is a cross-platform benchmark that measures a processor’s single-core performance. (Source: Primate Labs, 2022)
7.Blender (bmw27) result
Unknown. Help us by suggesting a value. (AMD A10-5800K)
Unknown. Help us by suggesting a value. (Intel Core i3-4130)
The Blender (bmw27) benchmark measures the performance of a processor by rendering a 3D scene. More powerful processors can render the scene in less time.
8.Blender (classroom) result
Unknown. Help us by suggesting a value. (AMD A10-5800K)
Unknown. Help us by suggesting a value. (Intel Core i3-4130)
The Blender (classroom) benchmark measures the performance of a processor by rendering a 3D scene. More powerful processors can render the scene in less time.
9.performance per watt
Unknown. Help us by suggesting a value. (Intel Core i3-4130)
This means the CPU is more efficient, giving a greater amount of performance for each watt of power used.
Features
1.uses multithreading
✖AMD A10-5800K
✔Intel Core i3-4130
Multithreading technology (such as Intel’s Hyperthreading or AMD’s Simultaneous Multithreading) provides increased performance by splitting each of the processor’s physical cores into virtual cores, also known as threads. This way, each core can run two instruction streams at once.
2.Has AES
✔AMD A10-5800K
✔Intel Core i3-4130
AES is used to speed up encryption and decryption.
3.Has AVX
✔AMD A10-5800K
✔Intel Core i3-4130
AVX is used to help speed up calculations in multimedia, scientific and financial apps, as well as improving Linux RAID software performance.
4.SSE version
SSE is used to speed up multimedia tasks such as editing an image or adjusting audio volume. Each new version contains new instructions and improvements.
5.Has F16C
✔AMD A10-5800K
✔Intel Core i3-4130
F16C is used to speed up tasks such as adjusting the contrast of an image or adjusting volume.
6.bits executed at a time
Unknown. Help us by suggesting a value. (AMD A10-5800K)
Unknown. Help us by suggesting a value. (Intel Core i3-4130)
NEON provides acceleration for media processing, such as listening to MP3s.
7.Has MMX
✔AMD A10-5800K
✔Intel Core i3-4130
MMX is used to speed up tasks such as adjusting the contrast of an image or adjusting volume.
8.Has TrustZone
✖AMD A10-5800K
✖Intel Core i3-4130
A technology integrated into the processor to secure the device for use with features such as mobile payments and streaming video using digital rights management (DRM).
9.front-end width
Unknown. Help us by suggesting a value. (AMD A10-5800K)
Unknown. Help us by suggesting a value. (Intel Core i3-4130)
The CPU can decode more instructions per clock (IPC), meaning that the CPU performs better
Price comparison
Cancel
Which are the best CPUs?
Intel Core i3-9100F vs AMD A10-6790K
Comparative analysis of Intel Core i3-9100F and AMD A10-6790K processors for all known characteristics in the following categories: Essentials, Performance, Memory, Compatibility, Peripherals, Security & Reliability, Advanced Technologies, Virtualization, Graphics, Graphics interfaces, Graphics API support.
Benchmark processor performance analysis: PassMark — Single thread mark, PassMark — CPU mark, Geekbench 4 — Single Core, Geekbench 4 — Multi-Core, 3DMark Fire Strike — Physics Score, CompuBench 1.5 Desktop — Face Detection (mPixels/s), CompuBench 1.5 Desktop — Ocean Surface Simulation (Frames/s), CompuBench 1.5 Desktop — T-Rex (Frames/s), CompuBench 1.5 Desktop — Video Composition (Frames/s), CompuBench 1.5 Desktop — Bitcoin Mining (mHash/s), GFXBench 4.0 — Manhattan (Frames), GFXBench 4.0 — T-Rex (Frames), GFXBench 4.0 — Manhattan (Fps), GFXBench 4.0 — T-Rex (Fps).
Intel Core i3-9100F
Buy on Amazon
vs
AMD A10-6790K
Buy on Amazon
Differences
Reasons to consider the Intel Core i3-9100F
- CPU is newer: launch date 5 year(s) 6 month(s) later
- Around 35% higher maximum core temperature: 100 °C vs 74°C
- A newer manufacturing process allows for a more powerful, yet cooler running processor: 14 nm vs 32 nm SOI
- Around 54% lower typical power consumption: 65 Watt vs 100 Watt
- Around 61% better performance in PassMark — Single thread mark: 2516 vs 1560
- 2. 2x better performance in PassMark — CPU mark: 6769 vs 3072
- 2x better performance in Geekbench 4 — Single Core: 1078 vs 527
- 2.3x better performance in Geekbench 4 — Multi-Core: 3394 vs 1464
Launch date | 23 April 2019 vs October 2013 |
Maximum core temperature | 100 °C vs 74°C |
Manufacturing process technology | 14 nm vs 32 nm SOI |
Thermal Design Power (TDP) | 65 Watt vs 100 Watt |
PassMark — Single thread mark | 2516 vs 1560 |
PassMark — CPU mark | 6769 vs 3072 |
Geekbench 4 — Single Core | 1078 vs 527 |
Geekbench 4 — Multi-Core | 3394 vs 1464 |
Reasons to consider the AMD A10-6790K
- Processor is unlocked, an unlocked multiplier allows for easier overclocking
- Around 2% higher clock speed: 4. 3 GHz vs 4.20 GHz
Unlocked | Unlocked vs Locked |
Maximum frequency | 4.3 GHz vs 4.20 GHz |
Compare benchmarks
CPU 1: Intel Core i3-9100F
CPU 2: AMD A10-6790K
PassMark — Single thread mark |
|
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PassMark — CPU mark |
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Geekbench 4 — Single Core |
|
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Geekbench 4 — Multi-Core |
|
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Name | Intel Core i3-9100F | AMD A10-6790K |
---|---|---|
PassMark — Single thread mark | 2516 | 1560 |
PassMark — CPU mark | 6769 | 3072 |
Geekbench 4 — Single Core | 1078 | 527 |
Geekbench 4 — Multi-Core | 3394 | 1464 |
3DMark Fire Strike — Physics Score | 3666 | |
CompuBench 1. 5 Desktop — Face Detection (mPixels/s) | 4.233 | |
CompuBench 1.5 Desktop — Ocean Surface Simulation (Frames/s) | 16.537 | |
CompuBench 1.5 Desktop — T-Rex (Frames/s) | 0.536 | |
CompuBench 1.5 Desktop — Video Composition (Frames/s) | 11.913 | |
CompuBench 1.5 Desktop — Bitcoin Mining (mHash/s) | 71.233 | |
GFXBench 4.0 — Manhattan (Frames) | 2797 | |
GFXBench 4. 0 — T-Rex (Frames) | 5588 | |
GFXBench 4.0 — Manhattan (Fps) | 2797 | |
GFXBench 4.0 — T-Rex (Fps) | 5588 |
Compare specifications (specs)
Intel Core i3-9100F | AMD A10-6790K | |
---|---|---|
Architecture codename | Coffee Lake | Richland |
Launch date | 23 April 2019 | October 2013 |
Launch price (MSRP) | $389 | |
Place in performance rating | 851 | 844 |
Processor Number | i3-9100F | |
Vertical segment | Desktop | Desktop |
Family | AMD A-Series Processors | |
OPN PIB | AD679KWOHLBOX | |
OPN Tray | AD679KWOA44HL | |
Series | AMD A10-Series APU for Desktops | |
64 bit support | ||
Base frequency | 3. 60 GHz | 4 GHz |
Bus Speed | 8 GT/s DMI | |
Manufacturing process technology | 14 nm | 32 nm SOI |
Maximum core temperature | 100 °C | 74°C |
Maximum frequency | 4.20 GHz | 4.3 GHz |
Number of cores | 4 | 4 |
Number of threads | 4 | 4 |
Unlocked | ||
Die size | 246 mm | |
L1 cache | 192 KB | |
L2 cache | 4 MB | |
Maximum case temperature (TCase) | 74 °C | |
Transistor count | 1178 million | |
ECC memory support | ||
Max memory channels | 2 | 2 |
Maximum memory bandwidth | 37. 5 GB/s | |
Maximum memory size | 64 GB | |
Supported memory types | DDR4-2400 | DDR3 |
Supported memory frequency | 1866 MHz | |
Max number of CPUs in a configuration | 1 | 1 |
Sockets supported | FCLGA1151 | FM2 |
Thermal Design Power (TDP) | 65 Watt | 100 Watt |
Max number of PCIe lanes | 16 | |
PCI Express revision | 3. 0 | 2.0 |
PCIe configurations | 1×16, 2×8, 1×8+2×4 | |
Execute Disable Bit (EDB) | ||
Intel® Identity Protection technology | ||
Intel® Memory Protection Extensions (Intel® MPX) | ||
Intel® OS Guard | ||
Intel® Secure Key technology | ||
Intel® Software Guard Extensions (Intel® SGX) | ||
Intel® Trusted Execution technology (TXT) | ||
Enhanced Intel SpeedStep® technology | ||
Idle States | ||
Instruction set extensions | Intel SSE4. 1, Intel SSE4.2, Intel AVX2 | |
Integrated Intel® QuickAssist Technology | ||
Intel® AES New Instructions | ||
Intel® Hyper-Threading technology | ||
Intel® Optane™ Memory Supported | ||
Intel® Stable Image Platform Program (SIPP) | ||
Intel® TSX-NI | ||
Intel® Turbo Boost technology | ||
Intel® vPro™ Platform Eligibility | ||
Thermal Monitoring | ||
AMD App Acceleration | ||
AMD Elite Experiences | ||
AMD HD3D technology | ||
Enhanced Virus Protection (EVP) | ||
Fused Multiply-Add (FMA) | ||
Fused Multiply-Add 4 (FMA4) | ||
Intel® Advanced Vector Extensions (AVX) | ||
PowerGating | ||
PowerNow | ||
VirusProtect | ||
Intel® Virtualization Technology (VT-x) | ||
Intel® Virtualization Technology for Directed I/O (VT-d) | ||
Intel® VT-x with Extended Page Tables (EPT) | ||
AMD Virtualization (AMD-V™) | ||
IOMMU 2. 0 | ||
Enduro | ||
Graphics max frequency | 844 MHz | |
iGPU core count | 384 | |
Number of pipelines | 384 | |
Processor graphics | AMD Radeon HD 8670D | |
Switchable graphics | ||
Unified Video Decoder (UVD) | ||
Video Codec Engine (VCE) | ||
DisplayPort | ||
HDMI | ||
DirectX | 11 |
AMD A10-9700 vs Intel Core i3-10100
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AMD A10-9700 vs Intel Core i3-10100
Comparison of the technical characteristics between the processors, with the AMD A10-9700 on one side and the Intel Core i3-10100 on the other side. The first is dedicated to the desktop sector, It has 4 cores, 4 threads, a maximum frequency of 3,8GHz. The second is used on the desktop segment, it has a total of 4 cores, 8 threads, its turbo frequency is set to 4,3 GHz. The following table also compares the lithography, the number of transistors (if indicated), the amount of cache memory, the maximum RAM memory capacity, the type of memory accepted, the release date, the maximum number of PCIe lanes, the values obtained in Geekbench 4 and Cinebench R15.
Note: Commissions may be earned from the links above.
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Specifications:
Processor | AMD A10-9700 | Intel Core i3-10100 | ||||||
Market (main) | Desktop | Desktop | ||||||
ISA | x86-64 (64 bit) | x86-64 (64 bit) | ||||||
Microarchitecture | Excavator | Comet Lake | ||||||
Core name | Bristol Ridge | Comet Lake-S | ||||||
Family | A10-9000 | Core i3-10000 | ||||||
Part number(s), S-Spec | AD9700AGABBOX, AD9700AGM44AB |
BX8070110100, BXC8070110100, CM8070104291317, QTP6, SRh4N |
||||||
Release date | Q3 2017 | Q2 2020 | ||||||
Lithography | 28 nm | 14 nm+++ | ||||||
Transistors | 3. 100.000.000 | — | ||||||
Cores | 4 | 4 | ||||||
Threads | 4 | 8 | ||||||
Base frequency | 3,5 GHz | 3,6 GHz | ||||||
Turbo frequency | 3,8 GHz | 4,3 GHz | ||||||
Cache memory | 2 MB | 6 MB | ||||||
Max memory capacity | 32 GB | 128 GB | ||||||
Memory types | DDR4-2400 | DDR4-2666 | ||||||
Max # of memory channels | 2 | 2 | ||||||
Max memory bandwidth | 38,4 GB/s | 41,6 GB/s | ||||||
Max PCIe lanes | 8 | 16 | ||||||
TDP | 65 W | 65 W | ||||||
Suggested PSU | 600W ATX Power Supply | 600W ATX Power Supply | ||||||
GPU integrated graphics | AMD Radeon R7 Graphics (Bristol) | Intel UHD Graphics 630 (Comet Lake) | ||||||
GPU cores | 8 | — | ||||||
GPU execution units | — | 24 | ||||||
GPU shading units | 512 | 192 | ||||||
GPU base clock | 200 MHz | 350 MHz | ||||||
GPU boost clock | 1029 MHz | 1100 MHz | ||||||
GPU FP32 floating point | 737,3 GFLOPS | 460,8 GFLOPS | ||||||
Socket | AM4 | LGA1200 | ||||||
Compatible motherboard | Socket AM4 Motherboard | Socket LGA 1200 Motherboard | ||||||
Maximum temperature | 90°C | 100°C | ||||||
Cinebench R15 single thread | 90 | 184 | ||||||
Cinebench R15 multi-thread | 301 | 905 | ||||||
Cinebench R20 single thread | 172 | 440 | ||||||
Cinebench R20 multi-thread | 578 | 2. 181 | ||||||
PassMark single thread | 1.633 | 2.638 | ||||||
PassMark CPU Mark | 3.585 | 8.934 | ||||||
(Windows 64-bit) Geekbench 4 single core |
2.355 | 5.101 | ||||||
(Windows 64-bit) Geekbench 4 multi-core |
5.789 | 16.447 | ||||||
(Windows) Geekbench 5 single core |
513 | 1.105 | ||||||
(Windows) Geekbench 5 multi-core |
1.559 | 4.164 | ||||||
(SGEMM) GFLOPS performance |
59,82 GFLOPS | 342,9 GFLOPS | ||||||
(Multi-core / watt performance) Performance / watt ratio |
89 pts / W | 253 pts / W | ||||||
Amazon | ||||||||
eBay |
Note: Commissions may be earned from the links above.
We can better compare what are the technical differences between the two processors.
Suggested PSU: We assume that we have An ATX computer case, a high end graphics card, 16GB RAM, a 512GB SSD, a 1TB HDD hard drive, a Blu-Ray drive. We will have to rely on a more powerful power supply if we want to have several graphics cards, several monitors, more memory, etc.
Price: For technical reasons, we cannot currently display a price less than 24 hours, or a real-time price. This is why we prefer for the moment not to show a price. You should refer to the respective online stores for the latest price, as well as availability.
We see that the two processors have an equivalent number of cores, the turbo frequency of Intel Core i3-10100 is bigger, that their respective TDP are of the same order. The Intel Core i3-10100 was started more recently.
Performances :
Performance comparison between the two processors, for this we consider the results generated on benchmark software such as Geekbench 4.
Cinebench R15 — Multi-thread & single thread score | |
---|---|
Intel Core i3-10100 |
184 905 |
AMD A10-9700 |
90 301 |
In single core, the difference is 104%. In multi-core, the difference in terms of gap is 201%.
Note: Commissions may be earned from the links above. These scores are only an
average of the performances got with these processors, you may get different results.
Cinebench R15 evaluates the performance of CPU calculations by restoring a photorealistic 3D scene. The scene has 2,000 objects, 300,000 polygons, uses sharp and fuzzy reflections, bright areas, shadows, procedural shaders, antialiasing, and so on. The faster the rendering of the scene is created, the more powerful the PC is, with a high number of points.
Cinebench R20 — Multi-thread & single thread score | |
---|---|
Intel Core i3-10100 |
440 2.181 |
AMD A10-9700 |
172 578 |
In single core, the difference is 156%. In multi-core, the difference in terms of gap is 277%.
Note: Commissions may be earned from the links above. These scores are only an
average of the performances got with these processors, you may get different results.
Cinebench R20 is a multi-platform test software which allows to evaluate the hardware capacities of a device such as a computer, a tablet, a server. This version of Cinebench takes into account recent developments in processors with multiple cores and the latest improvements in rendering techniques. The evaluation is ultimately even more relevant.
PassMark — CPU Mark & single thread | |
---|---|
Intel Core i3-10100 |
2.638 8.934 |
AMD A10-9700 |
1.633 3.585 |
In single core, the difference is 62%. In multi-core, the difference in terms of gap is 149%.
Note: Commissions may be earned from the links above. These scores are only an
average of the performances got with these processors, you may get different results.
PassMark is a benchmarking software that performs several performance tests including prime numbers, integers, floating point, compression, physics, extended instructions, encoding, sorting. The higher the score is, the higher is the device capacity.
On Windows 64-bit:
Geekbench 4 — Multi-core & single core score — Windows 64-bit | |
---|---|
Intel Core i3-10100 |
5. 101 16.447 |
AMD A10-9700 |
2.355 5.789 |
In single core, the difference is 117%. In multi-core, the difference in terms of gap is 184%.
On Linux 64-bit:
Geekbench 4 — Multi-core & single core score — Linux 64-bit | |
---|---|
Intel Core i3-10100 |
4.771 14.186 |
AMD A10-9700 |
2.281 5.039 |
In single core, the difference is 109%. In multi-core, the difference in terms of gap is 182%.
Note: Commissions may be earned from the links above. These scores are only an
average of the performances got with these processors, you may get different results.
Geekbench 4 is a complete benchmark platform with several types of tests, including data compression, images, AES encryption, SQL encoding, HTML, PDF file rendering, matrix computation, Fast Fourier Transform, 3D object simulation, photo editing, memory testing. This allows us to better visualize the respective power of these devices. For each result, we took an average of 250 values on the famous benchmark software.
On Windows:
Geekbench 5 — Multi-core & single core score — Windows | |
---|---|
Intel Core i3-10100 |
1.105 4.164 |
AMD A10-9700 |
513 1.559 |
In single core, the difference is 115%. In multi-core, the difference in terms of gap is 167%.
On Linux:
Geekbench 5 — Multi-core & single core score — Linux | |
---|---|
Intel Core i3-10100 |
1.171 4.181 |
AMD A10-9700 |
538 1.243 |
In single core, the difference is 118%. In multi-core, the difference in terms of gap is 236%.
Note: Commissions may be earned from the links above. These scores are only an
average of the performances got with these processors, you may get different results.
Geekbench 5 is a software for measuring the performance of a computer system, for fixed devices, mobile devices, servers. This platform makes it possible to better compare the power of the CPU, the computing power and to compare it with similar or totally different systems. Geekbench 5 includes new workloads that represent work tasks and applications that we can find in reality.
Equivalence:
AMD A10-9700 Intel equivalentIntel Core i3-10100 AMD equivalent
See also:
Intel Core i3-10100FIntel Core i3-10100TIntel Core i3-10100YIntel Core i3-10105Intel Core i3-10105FIntel Core i3-10105T
Intel Core i3-10100 vs AMD A10-9700
Summary
-
Intel Core i3-10100
297%
-
AMD A10-9700
100%
Relative performance
-
Intel Core i3-10100
297%
-
AMD A10-9700
100%
Relative performance
Reasons to consider Intel Core i3-10100 |
Much higher single threaded performance (around 197% higher), makes a noticeable performance difference in gaming and the majority of applications. |
This is a newer product, it might have better application compatibility/performance (check features chart below). |
Around 197% higher average synthetic performance. |
Reasons to consider AMD A10-9700 |
None |
Gaming
HWBench recommends Intel Core i3-10100
Based on game and synthetic benchmarks, and theoretical specifications.
Productivity
HWBench recommends Intel Core i3-10100
Based on productivity benchmarks, overall multithreaded performance and theoretical specifications.
Features
Intel Core i3-10100 | AMD A10-9700 | |||
---|---|---|---|---|
MMX | ||||
SSE | ||||
SSE2 | ||||
SSE3 | ||||
SSSE3 | ||||
SSE4.2 | ||||
AVX | ||||
AVX2 | ||||
EIST | ||||
Intel 64 | ||||
XD bit | ||||
VT-x | ||||
VT-d | ||||
AES-NI | ||||
TSX | ||||
TXT | ||||
CLMUL | ||||
FMA3 | ||||
F16C | ||||
BMI1 | ||||
BMI2 | ||||
ABM | ||||
ADX | ||||
RdRand | ||||
TBT 2. 0 | ||||
3DNow! | ||||
SSE4A | ||||
AMD64 | ||||
CnQ | ||||
NX bit | ||||
AMD-V |
Architecture
Intel Core i3-10100 | AMD A10-9700 | |||
---|---|---|---|---|
Architecture | Intel_Cometlake | vs | AMD Excavator | |
Market | Desktop | vs | Desktop | |
Memory Support | DDR4-2666 MHz Dual-channel |
vs | DDR4 | |
Codename | Comet Lake | vs | Bristol Ridge | |
Release Date | Apr 2020 | vs | Sep 2016 |
Cores
Intel Core i3-10100 | AMD A10-9700 | |||
---|---|---|---|---|
Cores | 4 | vs | 4 | |
Threads | 8 | vs | 4 | |
SMPs | 1 | vs | 1 | |
Integrated Graphics | UHD Graphics 630 | vs | Radeon R7 |
Cache
Intel Core i3-10100 | AMD A10-9700 | |||
---|---|---|---|---|
L1 Cache | 64K (per core) | vs | 128 KB (per core) | |
L2 Cache | 256K (per core) | vs | 512 KB (per core) | |
L3 Cache | 6MB (shared) | vs | 0 KB |
Physical
Intel Core i3-10100 | AMD A10-9700 | |||
---|---|---|---|---|
Socket | Intel Socket 1200 | vs | AMD Socket AM4 | |
Max Case Temp | 72°C | vs | unknown | |
Package | FC-LGA1200 | vs | uPGA | |
Die Size | unknown | vs | unknown | |
Process | 14 nm | vs | 14 nm |
Performance
Intel Core i3-10100 | AMD A10-9700 | |||
---|---|---|---|---|
Cpu Frequency | 3600 MHz | vs | 3500 MHz | |
Turbo Clock | 4300 MHz | vs | 3800 MHz | |
Base Clock | 100 MHz | vs | 100 MHz | |
Voltage | N/A | vs | unknown | |
TDP | 65 W | vs | 65 W |
-
Intel Core i3-10100
5160 points
-
AMD A10-9700
2622 points
Points — higher is better
-
Intel Core i3-10100
20736 points
-
AMD A10-9700
8404 points
Points — higher is better
-
Intel Core i3-10100 (simulated)
239. 19
-
AMD A10-9700 (simulated)
80.52
points — higher is better
Intel Core i3-4010U vs. AMD A10-7400P
Intel Core i3-4010U
The Intel Core i3-4010U operates with 2 cores and 4 CPU threads. It run at No turbo base No turbo all cores while the TDP is set at 15 W.The processor is attached to the BGA 1168 CPU socket. This version includes 3.00 MB of L3 cache on one chip, supports 2 memory channels to support DDR3L-1600 SO-DIMM RAM and features 2.0 PCIe Gen 12 lanes. Tjunction keeps below — degrees C. In particular, Haswell U Architecture is enhanced with 22 nm technology and supports VT-x, VT-x EPT, VT-d. The product was launched on Q3/2013
AMD A10-7400P
The AMD A10-7400P operates with 4 cores and 4 CPU threads. It run at 3.00 GHz base 3.40 GHz all cores while the TDP is set at 35 W.The processor is attached to the FM2+ CPU socket. This version includes 4.00 MB of L3 cache on one chip, supports 2 memory channels to support DDR3-1866 RAM and features 3. 0 PCIe Gen 16 lanes. Tjunction keeps below — degrees C. In particular, Kaveri (Steamroller) Architecture is enhanced with 28 nm technology and supports AMD-V. The product was launched on Q2/2014
Intel Core i3-4010U
AMD A10-7400P
Compare Detail
1.70 GHz | Frequency | 2.50 GHz |
2 | Cores | 4 |
No turbo | Turbo (1 Core) | 3.00 GHz |
No turbo | Turbo (All Cores) | 3.40 GHz |
Yes | Hyperthreading | No |
No | Overclocking | No |
normal | Core Architecture | normal |
Intel HD Graphics 4400 |
GPU |
AMD Radeon R6 (Kaveri) |
1.00 GHz | GPU (Turbo) | 0.65 GHz |
22 nm | Technology | 28 nm |
1.00 GHz | GPU (Turbo) | 0. 65 GHz |
11.1 | DirectX Version | 12 |
3 | Max. displays | 2 |
DDR3L-1600 SO-DIMM | Memory | DDR3-1866 |
2 | Memory channels | 2 |
Max memory | ||
No | ECC | Yes |
— | L2 Cache | — |
3.00 MB | L3 Cache | 4.00 MB |
2.0 | PCIe version | 3.0 |
12 | PCIe lanes | 16 |
22 nm | Technology | 28 nm |
BGA 1168 | Socket | FM2+ |
15 W | TDP | 35 W |
VT-x, VT-x EPT, VT-d | Virtualization | AMD-V |
Q3/2013 | Release date | Q2/2014 |
Show more data |
Show more data |
Cinebench R15 (Single-Core)
Cinebench R15 is the successor of Cinebench 11. 5 and is also based on the Cinema 4 Suite. Cinema 4 is a worldwide used software to create 3D forms. The single-core test only uses one CPU core, the amount of cores or hyperthreading ability doesn’t count.
Cinebench R15 (Multi-Core)
Cinebench R15 is the successor of Cinebench 11.5 and is also based on the Cinema 4 Suite. Cinema 4 is a worldwide used software to create 3D forms. The multi-core test involves all CPU cores and taks a big advantage of hyperthreading.
Geekbench 5, 64bit (Single-Core)
Geekbench 5 is a cross plattform benchmark that heavily uses the systems memory. A fast memory will push the result a lot. The single-core test only uses one CPU core, the amount of cores or hyperthreading ability doesn’t count.
Geekbench 5, 64bit (Multi-Core)
Geekbench 5 is a cross plattform benchmark that heavily uses the systems memory. A fast memory will push the result a lot. The multi-core test involves all CPU cores and taks a big advantage of hyperthreading.
iGPU — FP32 Performance (Single-precision GFLOPS)
The theoretical computing performance of the internal graphics unit of the processor with simple accuracy (32 bit) in GFLOPS. GFLOPS indicates how many billion floating point operations the iGPU can perform per second.
Geekbench 3, 64bit (Single-Core)
Geekbench 3 is a cross plattform benchmark that heavily uses the systems memory. A fast memory will push the result a lot. The single-core test only uses one CPU core, the amount of cores or hyperthreading ability doesn’t count.
Geekbench 3, 64bit (Multi-Core)
Geekbench 3 is a cross plattform benchmark that heavily uses the systems memory. A fast memory will push the result a lot. The multi-core test involves all CPU cores and taks a big advantage of hyperthreading.
Cinebench R11.5, 64bit (Single-Core)
Cinebench 11.5 is based on the Cinema 4D Suite, a software that is popular to generate forms and other stuff in 3D. The single-core test only uses one CPU core, the amount of cores or hyperthreading ability doesn’t count.
Cinebench R11.5, 64bit (Multi-Core)
Cinebench 11.5 is based on the Cinema 4D Suite, a software that is popular to generate forms and other stuff in 3D. The multi-core test involves all CPU cores and taks a big advantage of hyperthreading.
Cinebench R11.5, 64bit (iGPU, OpenGL)
Cinebench 11.5 is based on the Cinema 4D Suite, a software that is popular to generate forms and other stuff in 3D. The iGPU test uses the CPU internal graphic unit to execute OpenGL commands.
Estimated results for PassMark CPU Mark
Some of the CPUs listed below have been benchmarked by CPU-Comparison. However the majority of CPUs have not been tested and the results have been estimated by a CPU-Comparison’s secret proprietary formula. As such they do not accurately reflect the actual Passmark CPU mark values and are not endorsed by PassMark Software Pty Ltd.
Electric Usage Estimate
Average hours of use per day
Average CPU Utilization (0-100%)
Power cost, dollar per kWh
Electric Usage Estimate
Average hours of use per day
Average CPU Utilization (0-100%)
Power cost, dollar per kWh
Intel Core i3-4010U | AMD A10-7400P | |
15 W | Max TDP | 35 W |
NA | Power consumption per day (kWh) | NA |
NA | Running cost per day | NA |
NA | Power consumption per year (kWh) | NA |
NA | Running cost per year | NA |
Popular Comparision
Comments
AMD A10-4600M vs Intel Core i3-3110M: What is the difference?
43 BALLLA
AMD A10-4600M
38 BALLLA
Intel Core i3-3110M
Winter when comparing
VS
64 Facts compared to
AMD A10 Is A10-4600M better than Intel Core i3-3110M?
- 1. 92x higher CPU speed?
4 x 2.3GHz vs 2 x 2.4GHz - 3.5MB more L2 cache?
4MB vs 0.5MB - 64KB more L1 cache?
192KB vs 128KB - 0.75MB/core more L2 cache per core?
1MB/core vs 0.25MB/core - Has AES?
- Supports 1 more displays?
4 vs 3 - 0.1 newer version of OpenCL?
1.2 vs 1.1 - Has FMA4?
Why is Intel Core i3-3110M better than AMD A10-4600M?
- GPU frequency 154MHz higher?
650MHz vs 496MHz - Semiconductor size 10nm smaller?
22nm vs 32nm - 1.6x higher PassMark result?
3043 vs 1896 - 1 newer version of PCI Express (PCIe)?
3 vs 2 - 14.57% higher PassMark score (single)?
1219 vs 1064 - Multithreaded?
- 315MHz faster GPU turbo speed?
1000MHz vs 685MHz - 16. 0 higher performance per watt?
133.0 vs 117.0
Which comparisons are the most popular?
AMD A10-4600M
VS
Intel Core i5-3230M
Intel Core i3-31110M
VS
Intel Pentium Silver
AMD A10-4600M
VS 9000 AMD AMD AMD AMD AMD A100003
Intel Core i3-3110m
VS
A8-5550M
AMD A10-4600M
AMD A10-5750M
Intel Core I3-3110M
VS
Intel Core INTEL INTEL CORE AMD A10-4600M
VS
AMD A6-4400M
Intel Core i3-3110M
VS
AMD E-240
AMD A10-4600M
VS
Intel Core I5-4200U
-3110M
vs
AMD A4-4300M
AMD A10-4600M
VS
Intel Core i7-4600M
Intel Core i3-31110M
VS
AMD ATHLON II X2 270
000 ITEL ITEL ITEL ITEL IS
Intel Core i3-3110m
VS
Intel Core i3-2310m
AMD A10-4600M
Intel Core i5-3210m
VS 9000)
AMD A10-4600M
VS
AMD A10-46555M
Intel Core i3-3110m
VS
Intel Core i5-33804
Intel Core i3-3110M 9000 VS
9000 9000 9000
SOPE users
Performance
1. CPU speed
4 x 2.3GHz
2 x 2.4GHz
CPU speed indicates how many processing cycles per second the processor can perform, considering all its cores (processors). It is calculated by adding the clock speeds of each core or, in the case of multi-core processors, each group of cores.
2nd processor thread
More threads result in better performance and better multitasking.
3.speed turbo clock
3.2GHz
Unknown. Help us offer a price. (Intel Core i3-3110M)
When the processor is running below its limits, it can jump to a higher clock speed to increase performance.
4. Has an unlocked multiplier of
✖AMD A10-4600M
✖Intel Core i3-3110M
Some processors come with an unlocked multiplier and can be easily overclocked for better performance in games and other applications.
5. L2 Cache
More L2 scratchpad memory results in faster results in CPU and system performance tuning.
6.L3 cache
Unknown. Help us offer a price. (AMD A10-4600M)
More L3 scratchpad results in faster results in CPU and system performance tuning.
7.L1 cache
More L1 cache results in faster results in CPU and system performance tuning.
8.core L2
1MB/core
0.25MB/core
More data can be stored in the L2 scratchpad for access by each processor core.
9. L3 core
Unknown. Help us offer a price. (AMD A10-4600M)
1.5MB/core
More data can be stored in L3 scratchpad for access by each processor core.
Memory
1.RAM speed
1600MHz
1600MHz
Can support faster memory which speeds up system performance.
2.max memory bandwidth
Unknown. Help us offer a price. (AMD A10-4600M)
25.6GB/s
This is the maximum rate at which data can be read from or stored in memory.
3. DDR version
DDR (Dynamic Dynamic Random Access Memory Double Data Rate) is the most common type of RAM. New versions of DDR memory support higher maximum speeds and are more energy efficient.
4.Memory channels
More memory channels increase the speed of data transfer between memory and processor.
5.max memory
Unknown. Help us offer a price. (AMD A10-4600M)
Maximum amount of memory (RAM).
6.bus baud rate
Unknown. Help us offer a price. (AMD A10-4600M)
The bus is responsible for transferring data between various components of a computer or device.
7. Supports memory debug code
✖AMD A10-4600M
✖Intel Core i3-3110M
Memory debug code can detect and fix data corruption. It is used when necessary to avoid distortion, such as in scientific computing or when starting a server.
8.eMMC version
Unknown. Help us offer a price. (AMD A10-4600M)
Unknown. Help us offer a price. (Intel Core i3-3110M)
A newer version of eMMC — built-in flash memory — speeds up the memory interface, has a positive effect on device performance, for example, when transferring files from a computer to internal memory via USB.
9.bus frequency
Unknown. Help us offer a price. (AMD A10-4600M)
Unknown. Help us offer a price. (Intel Core i3-3110M)
The bus is responsible for transferring data between various components of a computer or device
Geotagging
1. PassMark result
This benchmark measures CPU performance using multi-threading.
2. PassMark result (single)
This test measures processor performance using a thread of execution.
3.Geekbench 5 result (multi-core)
Unknown. Help us offer a price. (AMD A10-4600M)
Unknown. Help us offer a price. (Intel Core i3-3110M)
Geekbench 5 is a cross-platform benchmark that measures the performance of a multi-core processor. (Source: Primate Labs,2022)
4. Cinebench R20 result (multi-core)
Unknown. Help us offer a price. (AMD A10-4600M)
Unknown. Help us offer a price. (Intel Core i3-3110M)
Cinebench R20 is a test that measures the performance of a multi-core processor by rendering a 3D scene.
5.Cinebench R20 result (single core)
Unknown. Help us offer a price. (AMD A10-4600M)
Unknown. Help us offer a price. (Intel Core i3-3110M)
Cinebench R20 is a test to evaluate the performance of a single core processor when rendering a 3D scene.
6.Geekbench 5 result (single core)
Unknown. Help us offer a price. (AMD A10-4600M)
Unknown. Help us offer a price. (Intel Core i3-3110M)
Geekbench 5 is a cross-platform test that measures the single-core performance of a processor. (Source: Primate Labs, 2022)
7. Blender test result (bmw27)
Unknown. Help us offer a price. (AMD A10-4600M)
Unknown. Help us offer a price. (Intel Core i3-3110M)
Blender benchmark (bmw27) measures CPU performance by rendering a 3D scene. More powerful processors can render a scene in a shorter time.
8.Blender result (classroom)
Unknown. Help us offer a price. (AMD A10-4600M)
Unknown. Help us offer a price. (Intel Core i3-3110M)
The Blender (classroom) benchmark measures CPU performance by rendering a 3D scene. More powerful processors can render a scene in a shorter time.
9.performance per watt
This means that the processor is more efficient, giving more performance per watt of power used.
Functions
1.uses multithreading
✖AMD A10-4600M
✔Intel Core i3-3110M
Multithreading technology (such as Intel’s Hyperthreading or AMD’s Simultaneous Multithreading) provides higher performance by dividing each physical processor core into logical cores, also known as flows. Thus, each core can run two instruction streams at the same time.
2. Has AES
✔AMD A10-4600M
✖Intel Core i3-3110M
AES is used to speed up encryption and decryption.
3. Has AVX
✔AMD A10-4600M
✔Intel Core i3-3110M
AVX is used to help speed up calculations in multimedia, scientific and financial applications, and to improve the performance of the Linux RAID program.
4.Version SSE
SSE is used to speed up multimedia tasks such as editing images or adjusting audio volume. Each new version contains new instructions and improvements.
5. Has F16C
✔AMD A10-4600M
✔Intel Core i3-3110M
F16C is used to speed up tasks such as image contrast adjustment or volume control.
6.bits transmitted at the same time
Unknown. Help us offer a price. (AMD A10-4600M)
Unknown. Help us offer a price. (Intel Core i3-3110M)
NEON provides faster media processing such as MP3 listening.
7.Has MMX
✔AMD A10-4600M
✔Intel Core i3-3110M
MMX is used to speed up tasks such as adjusting image contrast or adjusting volume.
8.Has TrustZone
✖AMD A10-4600M
✖Intel Core i3-3110M
Technology is integrated into the processor to ensure device security when using features such as mobile payments and video streaming using digital rights management (DRM) technology ).
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Unknown. Help us offer a price. (AMD A10-4600M)
Unknown. Help us offer a price. (Intel Core i3-3110M)
The processor can decode more instructions per clock (IPC), which means that the processor performs better
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Which CPUs are better?
Comparison of Intel Core i3-10100F and AMD A10-7850K
Comparative analysis of Intel Core i3-10100F and AMD A10-7850K processors by all known characteristics in the categories: General Information, Performance, Memory, Compatibility, Peripherals, Security and Reliability, Technology, Virtualization, Graphics, Graphical Interfaces, Graphics API Support.
Analysis of processor performance by benchmarks: PassMark — Single thread mark, PassMark — CPU mark, 3DMark Fire Strike — Physics Score, Geekbench 4 — Single Core, Geekbench 4 — Multi-Core, CompuBench 1.5 Desktop — Face Detection (mPixels/s), CompuBench 1. 5 Desktop — Ocean Surface Simulation (Frames/s), CompuBench 1.5 Desktop — T-Rex (Frames/s), CompuBench 1.5 Desktop — Video Composition (Frames/s), CompuBench 1.5 Desktop — Bitcoin Mining (mHash/s), GFXBench 4.0 — Car Chase Offscreen (Frames), GFXBench 4.0 — Manhattan (Frames), GFXBench 4.0 — T-Rex (Frames), GFXBench 4.0 — Car Chase Offscreen (Fps), GFXBench 4.0 — Manhattan (Fps), GFXBench 4.0 — T- Rex (Fps).
Intel Core i3-10100F
versus
AMD A10-7850K
Advantages
Reasons to choose Intel Core i3-10100F
- by 4 flows more: 8 VS 4
- About 8% more clock frequency: 4.30 GHZ VS 4 GHZ
- 38% higher maximum core temperature: 100°C vs 72.40°C
- Newer process technology allows the processor to be more powerful, but with lower power consumption: 14 nm vs 28 nm
- About 46% less power consumption: 65 Watt vs 95 Watt
- About 73% more performance in PassMark — Single thread mark: 2605 vs 1507
- 2. 6x more performance in PassMark — CPU mark: 8854 vs 3360
Number of threads | 8 vs 4 |
Maximum frequency | 4.30 GHz vs 4 GHz |
Maximum core temperature | 100°C vs 72.40°C |
Process | 14 nm vs 28 nm |
Power consumption (TDP) | 65 Watt vs 95 Watt |
PassMark — Single thread mark | 2605 vs 1507 |
PassMark — CPU mark | 8854 vs 3360 |
Reasons to choose AMD A10-7850K
- Unlocked CPU, unlocked multiplier allows easy overclocking
- 4 times larger L2 cache means more data can be stored in it for quick access
Unlocked | Unlocked / Locked |
Level 2 cache | 4MB vs 1MB |
Benchmark comparison
CPU 1: Intel Core i3-10100F
CPU 2: AMD A10-7850K
PassMark — Single thread mark |
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PassMark — CPU mark |
|
Name | Intel Core i3-10100F | AMD A10-7850K |
---|---|---|
PassMark — Single thread mark | 2605 | 1507 |
PassMark — CPU mark | 8854 | 3360 |
3DMark Fire Strike — Physics Score | 4877 | 0 |
Geekbench 4 — Single Core | 516 | |
Geekbench 4 — Multi-Core | 1576 | |
CompuBench 1. 5 Desktop — Face Detection (mPixels/s) | 5.183 | |
CompuBench 1.5 Desktop — Ocean Surface Simulation (Frames/s) | 16.998 | |
CompuBench 1.5 Desktop — T-Rex (Frames/s) | 0.316 | |
CompuBench 1.5 Desktop — Video Composition (Frames/s) | 0.799 | |
CompuBench 1.5 Desktop — Bitcoin Mining (mHash/s) | 5.104 | |
GFXBench 4.0 — Car Chase Offscreen (Frames) | 1781 | |
GFXBench 4. 0 — Manhattan (Frames) | 1947 | |
GFXBench 4.0 — T-Rex (Frames) | 5920 | |
GFXBench 4.0 — Car Chase Offscreen (Fps) | 1781 | |
GFXBench 4.0 — Manhattan (Fps) | 1947 | |
GFXBench 4.0 — T-Rex (Fps) | 5920 |
Feature comparison
Intel Core i3-10100F | AMD A10-7850K | |
---|---|---|
Architecture name | Comet Lake | Kaveri |
Issue date | Q4’20 | 14 January 2014 |
Price at first issue date | $79 — $97 | $173 |
Place in the rating | 505 | 1295 |
Processor Number | i3-10100F | |
Series | 10th Generation Intel Core i3 Processors | AMD A10-Series APU for Desktops |
Status | Launched | |
Applicability | Desktop | Desktop |
Family | AMD A-Series Processors | |
OPN PIB | AD785KXBJABOX | |
OPN Tray | AD785KXBI44JA | |
Support 64 bit | ||
Base frequency | 3. 60 GHz | 3.7 GHz |
Bus Speed | 8 GT/s | |
Level 1 cache | 256KB | 256KB |
Level 2 cache | 1MB | 4MB |
Level 3 cache | 6MB | |
Process | 14nm | 28nm |
Maximum core temperature | 100°C | 72.40°C |
Maximum frequency | 4.30 GHz | 4 GHz |
Number of cores | 4 | 4 |
Number of threads | 8 | 4 |
Compute Cores | 12 | |
Crystal area | 245mm | |
Maximum case temperature (TCase) | 74 °C | |
Number of GPU cores | 8 | |
Number of transistors | 2410 Million | |
Unlocked | ||
Maximum number of memory channels | 2 | 2 |
Maximum memory bandwidth | 41. 6 GB/s | |
Maximum memory size | 128GB | |
Supported memory types | DDR4-2666 | DDR3 |
Supported memory frequency | 2133MHz | |
Maximum number of processors in | 1 | 1 |
Package Size | 37.5mm x 37.5mm | |
Supported sockets | FCLGA1200 | FM2+ |
Power consumption (TDP) | 65 Watt | 95 Watt |
Thermal Solution | PCG 2015C | |
Number of PCI Express lanes | 16 | |
PCI Express revision | 3. 0 | 3.0 |
PCIe configurations | Up to 1×16, 2×8, 1×8+2×4 | |
Scalability | 1S Only | |
Execute Disable Bit (EDB) | ||
Intel® Identity Protection Technology | ||
Intel® OS Guard | ||
Intel® Secure Key Technology | ||
Intel® Software Guard Extensions (Intel® SGX) | ||
Intel® Trusted Execution Technology (TXT) | ||
Secure Boot | ||
Enhanced Intel SpeedStep® Technology | ||
Idle States | ||
Extended instructions | Intel SSE4. 1, Intel SSE4.2, Intel AVX2 | |
Intel 64 | ||
Intel® AES New Instructions | ||
Intel® Hyper-Threading Technology | ||
Intel® Optane™ Memory Supported | ||
Intel® Stable Image Platform Program (SIPP) | ||
Intel® Thermal Velocity Boost | ||
Intel® Turbo Boost Technology | ||
Thermal Monitoring | ||
AMD App Acceleration | ||
AMD Elite Experiences | ||
AMD HD3D technology | ||
AMD Mantle API | ||
DualGraphics | ||
Enhanced Virus Protection (EVP) | ||
Frame Rate Target Control (FRTC) | ||
FreeSync | ||
Fused Multiply-Add (FMA) | ||
Fused Multiply-Add 4 (FMA4) | ||
Heterogeneous System Architecture (HSA) | ||
Intel® Advanced Vector Extensions (AVX) | ||
Out-of-band client management | ||
PowerGating | ||
PowerNow | ||
System Image Stability | ||
TrueAudio | ||
VirusProtect | ||
Intel® Virtualization Technology (VT-x) | ||
Intel® Virtualization Technology for Directed I/O (VT-d) | ||
Intel® VT-x with Extended Page Tables (EPT) | ||
AMD Virtualization (AMD-V™) | ||
IOMMU 2. 0 | ||
Enduro | ||
Maximum GPU clock | 720MHz | |
Number of iGPU cores | 512 | |
Number of shaders | 512 | |
Integrated graphics | AMD Radeon R7 Graphics | |
Switchable graphics | ||
Unified Video Decoder (UVD) | ||
Video Codec Engine (VCE) | ||
DisplayPort | ||
HDMI | ||
DirectX | 12 | |
Vulcan |
Compare AMD A10 6800B vs.
Intel Core i3 3210
AMD A10 6800B
4.1 GHz | 4 cores
VS
Intel Core i3 3210
3.2GHz | 2 cores | LGA 1155
Benchmarks
Overall result
Based on 4 benchmarks:
AMD A10 6800B is 8.74% faster
get more performance with less heat generation 9
Integrated video
AMD106
44 | ||
Average power consumption | 81. 25 W | 44.69 W |
AMD A10-4600M vs Intel Core i3-7020U — comparative characteristics and benchmarks of processors
VS
AMD A10-4600M
Intel Core i3-7020U
Which one to choose?
It’s time to choose the winner. What is the difference and which is better in AMD A10-4600M vs Intel Core i3-7020U comparison? Which processor is more powerful and faster? It is quite simple to determine — look at the comparative table of all characteristics. A processor with more cores/threads, as well as a higher frequency and large L2-L3 is the absolute winner!
Cores, base and turbo frequency of the processor
Who will win in the comparison of AMD A10-4600M and Intel Core i3-7020U. The overall performance of a processor can be easily determined based on the number of cores, threads, base and turbo clock speed + L2-L3 volume. The more cores, L3, and clock speed, the more efficient the processor. Please note that high specifications require the use of a powerful cooling system.
2.30 GHz
Clock frequency
2.30 GHZ
4 9000
NO
Hypertureuding
YES
YES
Acceleration
NO
3.20 GHZ
TURBO
Family and generation of the processor
9000
Internal graphics
It’s hard to compare AMD A10-4600M vs. Intel Core i3-7020U when graphics card function and specs matter only in laptops. In workstations, this is not an advantage, due to the installation of an additional graphics accelerator.
AMD Radeon HD 7660g
004 4
Generation
9,0003
11.2
version DirectX
12
6
Executive blocks
24
384
Number of shaders
192
9000 9000 32 9000 32000 Maximum memory 32 GB
2
Number of monitors
3
32 nm
Technology
14 nm
Q2/2012
Release date
0004 Q2/2016
Hardware codec support
Here we are dealing with specifications that are used by some processor manufacturers. These figures are mostly technical and can be disregarded for comparative purposes.
Decode
H364
Decode / Encode
Decode / Encode
JPEG
Decode / EncoDe0003
h365 10bit
Decode / Encode
No
VP8
Decode / Encode
No
VP9
Decode / Encode
No
VC-1
Decode
Decode
AVC
Decode / Encode
RAM and PCIe
These are the memory standards supported by processors. The processor can support multi-channel RAM with a high clock speed, this directly affects its speed and performance.
DDR3-1600
Type of memory
DDR4-2133 SO-Dimm
Maximum memory
32 GB
2
29000 2
ECC
9000 NO
9000 9000 Memory PCIe
Thermal management and TDP
Today’s systems are loaded with demanding games and workloads, which consequently unleash the full potential of the processor. When choosing between AMD A10-4600M and Intel Core i3-7020U, it is better to choose the option with less heat dissipation (TDP).
35 W
TDP
15 W
—
Maximum temperature
100 °C
—
Maximum TDP
—
—
TDP Down
7.5 W
4.00 MB
L3-CACHE
3.00 MB
32 NM 9000 Kaby Lake U
AMD-V
Virtualization
VT-X, VT-X EPT, VT-D
FS1R2
SOCKET (connector)
BGA 1356
004 Q3/2018
Price
ca. 281 $
Instruction set (ISA)
EM64T
L2-Cache
512 KB
Part Number
individual
It can be a desktop computer or a laptop.
Unknown
Used in
Notebooks — HP, ACER, DELL, ASUS
Cinebench R11.5, 64bit (Single-Core)
This synthetic benchmark will help you determine the actual processing power of a single CPU core. Cinebench R11.5 is based on MAXON CINEMA 4D and uses various test scenarios
AMD A10-4600M
4x 2.30 GHz (3.20 GHz)
78 (100%)
Intel Core i3-7020U
2x 2.30 GHz (No turbo) HT
Cinebench R11.5, 64bit (Multi-Core)
Cinebench R11.5 performs simultaneous cross-platform tests on all processor cores. Running realistic 3D scenes, this benchmark will unleash the full potential of your single-core Intel or AMD 9 processor0003
AMD A10-4600M
4x 2.30 GHz (3.20 GHz)
204 (100%)
Intel Core i3-7020U
2x 2. 30 GHz (No turbo) HT
Cinebench R11.5, 64bit (iGPU, OpenGL)
Cinebench 11.5 is based on Cinema 4D Suite, a popular software for creating shapes and other things in 3D. The iGPU test uses the processor’s internal graphics unit to execute OpenGL commands.
AMD A10-4600M
4x 2.30 GHz (3.20 GHz)
305 (100%)
Intel Core i3-7020U
2x 2.30 GHz (No turbo) HT
Cinebench R15 (Single Core)
The latter is used to create 3D models and shapes. Cinebench R15 is used to benchmark the performance of single core processors. Hyperthreading capability is not taken into account. It is an updated version of Cinebench 11.5. Like all new versions, the updated benchmark is based on Cinema 4 Suite 9 software0003
AMD A10-4600M
4x 2.30 GHz (3.20 GHz)
63 (67%)
Intel Core i3-7020U
2x 2.30 GHz (No turbo) HT
94 (100%)
Cinebench R15 (Multi-Core)
Cinebench R15 can be used to test the performance of multi-core processors. The test produces accurate and reliable results. This benchmark is an updated version of Cinebench 11.5, which is based on Cinema 4 Suite soft.
AMD A10-4600M
4x 2. 30 GHz (3.20 GHz)
186 (81%)
Intel Core i3-7020U
2x 2.30 GHz (No turbo) HT
227 (100%)
Geekbench 3, 64bit (Single-Core)
Geekbench 3 is a benchmark for 64-bit Intel and AMD processors. It uses a new power rating system for a single processor core. This software simulates real scenarios for accurate results
AMD A10-4600M
4x 2.30 GHz (3.20 GHz)
1417 (63%)
Intel Core i3-7020U
2x 2.30 GHz (No turbo) HT
2226 (100%)
Geekbench 3, 64bit (Multi-Core)
Geekbench 3 supports multi-core AMD and Intel processors. Based on MAXON CINEMA 4D, it allows you to get the real comparative potential of the processor
AMD A10-4600M
4x 2.30 GHz (3.20 GHz)
3992 (82%)
Intel Core i3-7020U
2x 2.30 GHz (No turbo) HT
4861 (100%)
Geekbench 5, 64bit (Single-Core)
Geekbench 5 is the latest software. Completely new algorithms provide fairly accurate test results for single-core processors.
AMD A10-4600M
4x 2.30 GHz (3.20 GHz)
355 (63%)
Intel Core i3-7020U
2x 2. 30 GHz (No turbo) HT
560 (100%)
Geekbench 5, 64bit (Multi-Core)
Geekbench 5 benchmark results for memory performance and multi-core processor speed. This takes into account the ability to hyperthreading.
AMD A10-4600M
4x 2.30 GHz (3.20 GHz)
916 (72%)
Intel Core i3-7020U
2x 2.30 GHz (No turbo) HT
1263 (100%)
Blender 2.81 (bmw27)
We use the Blender benchmark to monitor CPU performance. Test results show how fast the device performs when performing multi-processor tasks
AMD A10-4600M
4x 2. 30 GHz (3.20 GHz)
Intel Core i3-7020U
2x 2.30 GHz (No turbo) HT
14112 (100%)
Estimated results for PassMark CPU Mark
It tests all and general CPU performance (math calculations, compression and decompression speed, 2D&3D graphics tests). Please note that data may differ from actual situations.
AMD A10-4600M
4x 2.30 GHz (3.20 GHz)
3148 (88%)
Intel Core i3-7020U
2x 2.30 GHz (No turbo) HT
3539 (100%)
iGPU — FP32 Performance (Single-precision GFLOPS)
This test measures the performance of integrated graphics on Intel and AMD processors. The result is the calculated processing power in Single-Precision mode FP32
AMD A10-4600M
4x 2.30 GHz (3.20 GHz)
527 (100%)
Intel Core i3-7020U
2x 2.30 GHz (No turbo) HT
384 (72%)
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Intel Pentium N6415 Intel Core i3-7020U |
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fifteen. |
AMD A10-4600M vs. Intel Celeron 3765U |
AMD A10-5757M vs. Intel Core i3-4100M
AMD A10-5757M
AMD A10-5757M runs with 4 and 4 CPU threads It runs at 3. 50 GHz base 3.50 GHz all cores while TDP is set to 35 W .CPU connects to CPU socket FP2 This version includes 4.00 MB of L3 cache on a single die, supports 2 to support DDR3-1600 RAM, and supports PCIe Gen . Tjunction is kept below — degrees C. In particular, the Richland (Piledriver) architecture has been advanced over 32 nm and supports AMD-V . The product was launched Q2/2013
Intel Core i3-4100M
Intel Core i3-4100M works with 2 and 4 CPU threads It runs on No turbo base No turbo all cores while TDP is set to 37 W .The processor connects to a PGA 946 CPU socket This version includes 3.00 MB of L3 cache on a single die, supports 2 to support DDR3L-1333 SO-DIMM, DDR3L-1600 SO-DIMM RAM, and supports 2.0 PCIe Gen 16 . Tjunction is kept below 100°C degrees C. In particular, Haswell H architecture is advanced beyond 22 nm and supports VT-x, VT-x EPT, VT-d . The product was launched Q4/2013
AMD A10-5757M
Intel Core i3-4100M
AMD Radeon HD 8650G
Intel HD Graphics 4600
DDR3L-1600 SO-DIMM
Show more details
Show more details
Cinebench R15 (Single-Core)
Cinebench R15 is the successor to Cinebench 11.5 and is also based on Cinema 4 Suite. Cinema 4 is software used all over the world to create 3D forms. The single-core test uses only one CPU core, the number of cores or hyper-threading capability is not taken into account.
Cinebench R15 (Multi-Core)
Cinebench R15 is the successor to Cinebench 11.5 and is also based on the Cinema 4 Suite. Cinema 4 is software used all over the world to create 3D forms. The multi-core test uses all the CPU cores and gives a big advantage of hyper-threading.
Geekbench 5, 64bit (Single-Core)
Geekbench 5 is a memory-intensive, cross-platform benchmark. A fast memory will greatly push the result. The single-core test uses only one CPU core, the number of cores or hyper-threading capability is not taken into account.
Geekbench 5, 64bit (Multi-Core)
Geekbench 5 is a memory-intensive, cross-platform test. A fast memory will greatly push the result. The multi-core test uses all the CPU cores and gives a big advantage of hyper-threading.
iGPU — FP32 Performance (Single-precision GFLOPS)
Theoretical processing performance of the processor’s internal graphics unit with simple precision (32 bits) in GFLOPS. GFLOPS specifies how many billions of floating point operations the iGPU can perform per second.
Geekbench 3, 64bit (Single-Core)
Geekbench 3 is a cross-platform benchmark that is memory intensive. A fast memory will greatly push the result. The single-core test uses only one CPU core, the number of cores or hyper-threading capability is not taken into account.
Geekbench 3, 64bit (Multi-Core)
Geekbench 3 is a cross-platform benchmark that is memory intensive. A fast memory will greatly push the result. The multi-core test uses all the CPU cores and gives a big advantage of hyper-threading.
Cinebench R11.5, 64bit (Single-Core)
Cinebench 11.5 is based on the Cinema 4D Suite, a software that is popular for creating shapes and other things in 3D. The single-core test uses only one CPU core, the number of cores or hyper-threading capability is not taken into account.
Cinebench R11.5, 64bit (Multi-Core)
Cinebench 11. 5 is based on Cinema 4D Suite, a software that is popular for creating shapes and other things in 3D. The multi-core test uses all the CPU cores and gives a big advantage of hyper-threading.
Estimated results for PassMark CPU Mark
Some of the processors listed below have been tested with CPU-Comparison. However, most of the processors were not tested and the results were evaluated by the secret patented CPU-Comparison formula. As such, they do not accurately reflect the actual values of Passmark CPU ratings and are not endorsed by PassMark Software Pty Ltd.
Energy usage estimate
Average hours of use per day
Average CPU usage (0-100%)
Cost of electricity, USD/kWh
Energy usage estimate
Average hours of use per day
Average CPU usage (0-100%)
Cost of electricity, USD/kWh
AMD A10-5757M | Intel Core i3-4100M | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
35 W | Max TDP | 37W | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
N. A. | Power consumption per day (kWh) | NA | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
NA | Operating cost per day | NA | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
NA | Power consumption per year (kWh) | NA | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
NA | Operating cost per year | NA |
Simple household tasks |
Core i3-2120 51.4 (+22%) A10-7800 APU (2014 D.Ka) 40.1 |
Demanding games and tasks |
Core i3-2120 18.5 A10-7800 APU (2014 D. Ka) 19.7 (+6.1%) |
Extreme |
Core i3-2120 3.6 A10-7800 APU (2014 D.Ka) 3.9 (+7.7%) |
Different tasks require different CPU strengths. A system with few fast cores and low memory latency will be fine for the vast majority of games, but will be inferior to a system with a lot of slow cores in a rendering scenario.
We believe that a minimum of 4/4 (4 physical cores and 4 threads) processor is suitable for a budget gaming PC. At the same time, some games can load it at 100%, slow down and freeze, and performing any tasks in the background will lead to a drop in FPS.
Ideally, the budget shopper should aim for a minimum of 4/8 and 6/6. A gamer with a big budget can choose between 6/12, 8/8 and 8/16. Processors with 10 and 12 cores can perform well in games with high frequency and fast memory, but are overkill for such tasks. Also, buying for the future is a dubious undertaking, since in a few years many slow cores may not provide sufficient gaming performance.
When choosing a processor for your work, consider how many cores your programs use. For example, photo and video editors can use 1-2 cores when working with filtering, and rendering or converting in the same editors already uses all threads.
Data obtained from tests by users who tested their systems both with overclocking (maximum value in the table) and without (minimum). A typical result is shown in the middle, the more filled in the color bar, the better the average result among all tested systems.
Characteristics
The data is not yet filled in, so the tables may lack information or existing functions may be omitted.
Basic
Manufacturer | Intel | AMD |
DescriptionInformation about the processor, taken from the official website of the manufacturer. | Intel® Core™ i3-2120 Processor (3M Cache, 3.30 GHz) | |
ArchitectureCode name for the microarchitecture generation. | Sandy Bridge | |
Process The manufacturing process, measured in nanometers. The smaller the technical process, the more perfect the technology, the lower the heat dissipation and power consumption. | 32 | No data |
Release dateMonth and year of the processor’s availability. | 09-2016 | 09-2017 |
Model Official name. | i3-2120 | |
Cores The number of physical cores. | 2 | 2 |
ThreadsNumber of threads. The number of logical processor cores that the operating system sees. | 4 | 4 |
Multi-Threading Technology With Intel’s Hyper-threading and AMD’s SMT technology, one physical core is recognized by the operating system as two logical cores, thereby increasing processor performance in multi-threaded applications. | Hyper-threading (note that some games may not work well with Hyper-threading, you can disable the technology in the BIOS of the motherboard for maximum FPS). | SMT (note that some games may not work well with SMT, for maximum FPS, you can disable the technology in the BIOS of the motherboard). |
Base frequencyGuaranteed frequency of all processor cores at maximum load. Performance in single-threaded and multi-threaded applications and games depends on it. It is important to remember that speed and frequency are not directly related. For example, a new processor at a lower frequency may be faster than an old one at a higher one. | 3.3 GHz | 3.5 GHz |
Turbo FrequencyThe maximum frequency of a single processor core in turbo mode. Manufacturers allow modern processors to independently increase the frequency of one or more cores under heavy load, due to which performance is noticeably increased. It may depend on the nature of the load, the number of loaded cores, temperature and the specified limits. Significantly affects the speed in games and applications that are demanding on the frequency of the CPU. | 3.3 GHz | 3.65 GHz |
L3 cache size The third level cache acts as a buffer between the computer’s RAM and the processor’s level 2 cache. Used by all cores, the speed of information processing depends on the volume. | 3 | No data |
Instructions | 64-bit | |
Extended instruction set Allows you to speed up calculations, processing and execution of certain operations. Also, some games require instruction support. | SSE4.1/4.2, AVX | |
Embedded Options Available Two enclosure versions. Standard and designed for mobile devices. In the second version, the processor can be soldered on the motherboard. | Yes | No |
Bus frequency The speed of communication with the system. | 5 GT/s DMI | |
Number of QPI links | ||
TDPThermal Design Power is an indicator that determines heat dissipation in standard operation. The cooler or water cooling system must be rated for a larger value. Remember that with a factory bus or manual overclocking, TDP increases significantly. | 65 | No data |
Cooling system specifications |
Video core
Integrated graphics core Allows you to use your computer without a discrete graphics card. The monitor is connected to the video output on the motherboard. If earlier integrated graphics made it possible to simply work at a computer, today it can replace budget video accelerators and makes it possible to play most games at low settings. | Intel® HD Graphics 2000 | |
GPU base clockFrequency in 2D and idle. | 850 | No data |
Max GPU ClockMaximum 3D clock. | 1100 | No data |
Intel® Wireless Display (Intel® WiDi) Supports Wireless Display technology over Wi-Fi 802.11n. Thanks to it, a monitor or TV equipped with the same technology does not require a cable to connect. | No data | |
Supported monitorsThe maximum number of monitors that can be connected to the integrated video core at the same time. | 2 |
RAM
Maximum amount of RAMThe amount of RAM that can be installed on the motherboard with this processor. | 32 | No data |
Supported type of RAM The type of RAM depends on its frequency and timings (speed), availability, price. | DDR3 1066/1333 | |
RAM Channels The multi-channel memory architecture increases data transfer speed. On desktop platforms, two-channel, three-channel and four-channel modes are available. | 2 | |
RAM bandwidth | 21 GB/s | |
ECC memory Support for error-correcting memory that is used in servers. Usually more expensive than usual and requires more expensive server components. However, second-hand server processors, Chinese motherboards and ECC memory sticks, which are sold relatively cheaply in China, have become widespread. | No data | No data |
PCI
PCI-E The PCI Express computer bus version. The bandwidth and power limit depend on the version. There is backward compatibility. | 2 | No data |
PCI configuration options | ||
Number of PCI lanes | 16 |
Data security
AES-NI The AES command set extension speeds up applications that use appropriate encryption. | No data | No data |
Intel® Secure Key An RDRAND instruction that allows you to create a high performance random number generator. | No data | No data |
Decoration
Dimensions | No data | No data |
Supported sockets | No data | No data |
Maximum processors per motherboard | No data | No data |
Which is better
Intel Core i3-2120
- On average, gaming performance is 9% better.
- The speed of work in office applications and browsers is increased by 11%.