Comparaison all cpu: Intel Core i5-8250U @ 1.60GHz vs Intel Core i5-7200U @ 2.50GHz [cpubenchmark.net] by PassMark Software

AMD Ryzen 5 5500U vs Intel Core i5-1135G7: What is the difference?

53points

AMD Ryzen 5 5500U

57points

Intel Core i5-1135G7

Comparison winner

vs

63 facts in comparison

AMD Ryzen 5 5500U

Intel Core i5-1135G7

Why is AMD Ryzen 5 5500U better than Intel Core i5-1135G7?

• 31.25% faster CPU speed?
  6 x 2.1GHzvs4 x 2.4GHz
• 4 more CPU threads?
  12vs8
• 3nm smaller semiconductor size?
  7nmvs10nm
• 30.74% higher PassMark result?
  13244vs10130
• 37.74% higher Cinebench R20 (multi) result?
  2573vs1868
• 500MHz faster GPU turbo speed?
  1800MHzvs1300MHz

Why is Intel Core i5-1135G7 better than AMD Ryzen 5 5500U?

• 100MHz faster GPU clock speed?
  400MHzvs300MHz
• 2MB bigger L2 cache?
  5MBvs3MB
• 1 newer version of PCI Express (PCIe)?
  4vs3
• 0. 75MB/core more L2 cache per core?
  1.25MB/corevs0.5MB/core
• 12.2% higher PassMark result (single)?
  2760vs2460
• 13.42% higher Cinebench R20 (single) result?
  524vs462
• 35.39% higher single-core Geekbench 5 result?
  1270vs938
• 0.67MB/core more L3 cache per core?
  2MB/corevs1.33MB/core

Which are the most popular comparisons?

AMD Ryzen 5 5500U

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Intel Core i3-1115G4

Intel Core i5-1135G7

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Intel Core i3-1115G4

AMD Ryzen 5 5500U

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Intel Core i5-10210U

Intel Core i5-1135G7

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AMD Ryzen 7 5700U

AMD Ryzen 5 5500U

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AMD Ryzen 5 5600H

Intel Core i5-1135G7

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AMD Ryzen 5 5625U

AMD Ryzen 5 5500U

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AMD Ryzen 7 5700U

Intel Core i5-1135G7

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Intel Core i7-1165G7

AMD Ryzen 5 5500U

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Intel Core i7-1165G7

Intel Core i5-1135G7

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Apple M1

AMD Ryzen 5 5500U

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Intel Core i5-1235U

Intel Core i5-1135G7

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Intel Core i5-1235U

AMD Ryzen 5 5500U

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AMD Ryzen 5 5625U

Intel Core i5-1135G7

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AMD Ryzen 5 4500U

AMD Ryzen 5 5500U

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AMD Ryzen 3 5300U

Intel Core i5-1135G7

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AMD Ryzen 7 3700U

AMD Ryzen 5 5500U

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AMD Ryzen 5 3500U

Intel Core i5-1135G7

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AMD Ryzen 5 3500U

Price comparison

User reviews

Overall Rating

AMD Ryzen 5 5500U

12 User reviews

AMD Ryzen 5 5500U

9. 3/10

12 User reviews

Intel Core i5-1135G7

16 User reviews

Intel Core i5-1135G7

9.0/10

16 User reviews

Features

Value for money

9.6/10

11 votes

9.1/10

16 votes

Gaming

8.7/10

12 votes

8.6/10

16 votes

Performance

9.7/10

12 votes

9.2/10

16 votes

Reliability

9.8/10

12 votes

9.4/10

16 votes

Energy efficiency

9.2/10

11 votes

9.0/10

16 votes

Performance

1.CPU speed

6 x 2.1GHz

4 x 2.4GHz

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

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 Ryzen 5 5500U

✖Intel Core i5-1135G7

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

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

1.25MB/core

More data can be stored in the L2 cache for access by each core of the CPU.

9.L3 core

1.33MB/core

2MB/core

More data can be stored in the L3 cache for access by each core of the CPU.

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)

Geekbench 5 is a cross-platform benchmark that measures a processor’s multi-core performance. (Source: Primate Labs, 2022)

4.Cinebench R20 (multi) result

Cinebench R20 is a benchmark tool that measures a CPU’s multi-core performance by rendering a 3D scene.

5.Cinebench R20 (single) result

Cinebench R20 is a benchmark tool that measures a CPU’s single-core performance by rendering a 3D scene.

6.Geekbench 5 result (single)

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 Ryzen 5 5500U)

Unknown. Help us by suggesting a value. (Intel Core i5-1135G7)

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 Ryzen 5 5500U)

Unknown. Help us by suggesting a value. (Intel Core i5-1135G7)

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 Ryzen 5 5500U)

Unknown. Help us by suggesting a value. (Intel Core i5-1135G7)

This means the CPU is more efficient, giving a greater amount of performance for each watt of power used.

Integrated graphics

1.GPU clock speed

300MHz

400MHz

The graphics processing unit (GPU) has a higher clock speed.

2.GPU turbo

1800MHz

1300MHz

When the GPU is running below its limitations, it can boost to a higher clock speed in order to give increased performance.

3.GPU execution units

A graphics processing unit (GPU) with a greater number of execution units can deliver better graphics.

4.supported displays

Using multiple displays you can create a larger workspace, making it easier to work across multiple apps.

5.DirectX version

DirectX is used in games, with newer versions supporting better graphics.

6.OpenGL version

OpenGL is used in games, with newer versions supporting better graphics.

7.OpenCL version

Some apps use OpenCL to apply the power of the graphics processing unit (GPU) for non-graphical computing. Newer versions introduce more functionality and better performance.

8.texture mapping units (TMUs)

TMUs take textures and map them to the geometry of a 3D scene. More TMUs will typically mean that texture information is processed faster.

9.render output units (ROPs)

The ROPs are responsible for some of the final steps of the rendering process, writing the final pixel data to memory and carrying out other tasks such as anti-aliasing to improve the look of graphics.

Memory

1.RAM speed

4266MHz

4267MHz

It can support faster memory, which will give quicker system performance.

2.maximum memory bandwidth

68.3GB/s

Unknown. Help us by suggesting a value. (Intel Core i5-1135G7)

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

The maximum amount of memory (RAM) supported.

6.bus transfer rate

Unknown. Help us by suggesting a value. (AMD Ryzen 5 5500U)

The bus is responsible for transferring data between different components of a computer or device.

7.Supports ECC memory

✖AMD Ryzen 5 5500U

✖Intel Core i5-1135G7

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 Ryzen 5 5500U)

Unknown. Help us by suggesting a value. (Intel Core i5-1135G7)

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 Ryzen 5 5500U)

Unknown. Help us by suggesting a value. (Intel Core i5-1135G7)

The bus is responsible for transferring data between different components of a computer or device.

Features

1.uses multithreading

✔AMD Ryzen 5 5500U

✔Intel Core i5-1135G7

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 Ryzen 5 5500U

✔Intel Core i5-1135G7

AES is used to speed up encryption and decryption.

3.Has AVX

✔AMD Ryzen 5 5500U

✔Intel Core i5-1135G7

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 Ryzen 5 5500U

✔Intel Core i5-1135G7

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 Ryzen 5 5500U)

Unknown. Help us by suggesting a value. (Intel Core i5-1135G7)

NEON provides acceleration for media processing, such as listening to MP3s.

7.Has MMX

✔AMD Ryzen 5 5500U

✔Intel Core i5-1135G7

MMX is used to speed up tasks such as adjusting the contrast of an image or adjusting volume.

8.Has TrustZone

✖AMD Ryzen 5 5500U

✖Intel Core i5-1135G7

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 Ryzen 5 5500U)

Unknown. Help us by suggesting a value. (Intel Core i5-1135G7)

The CPU can decode more instructions per clock (IPC), meaning that the CPU performs better

Price comparison

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Which are the best CPUs?

Cinebench R15 IPC Comparison Graphs — Articles — CPU Grade

Instruction throughput is one of several methods to determine a microprocessor’s performance. It is more commonly written as IPC, or instructions-per-clock. In order for a comparison of instruction throughput, all processors being compared must be operating at identical frequencies, with all turbo and low-power features disabled. A true instructions-per-clock comparison can’t be made if these criteria aren’t met.

The graphs below depict IPC improvements for architectures from both AMD and Intel over the past seven years.

Intel’s high-clocked Skylake-X processor leads the way with single-threaded performance. AMD’s Zen architecture gains an incredible lead over its predecessors, albeit, we must remember that Cinebench is a floating-point benchmark; by design, AMD’s construction core architectures contained half as many floating-point units as they did integer units, which is why they have always struggled in Cinebench. Happily however, Zen returns to a more balanced design, and that allows it to keep pace with Intel. AMD aimed to match Intel’s Broadwell-based Core i7-6900K in single-thread, and that is exactly what we can see here.

Also worth noting is that both AMD Piledriver-based chips achieve identical scores, however the A-Series variant lacks a Level 3 cache and must therefore depend on its 200 MHz higher core frequency to obtain the FX’s score.

Out-of-the-box single-threaded performance in Cinebench R15.

In order to initiate an instruction throughput comparison, we must first normalize the processors to one fixed frequency. All models will comfortably operate at 3.00 GHz, and in the case that we might want to add older architectures to the graphs at a later date, the lower frequency also ensures that we don’t need to start from scratch with what we have already. All architectures dating back to AMD’s K8 and Intel’s NetBurst are capable of reaching 3.00 GHz. Perfect.

At 3.00 GHz, the past three generations of Intel microprocessors suddenly find themselves very close to each other, while AMD’s Zen architecture squeezes between Broadwell and Skylake. The latter two architectures both show that they’re incremental updates at best.

Unsurprisingly, all AMD construction core architectures demonstrate poor performance here.

Normalized 3.00 GHz single-threaded performance in Cinebench R15.

Our final graph compares instruction throughput improvements, generation over generation, using AMD’s Bulldozer architecture as our 100% baseline.

Note: If you’re looking to compare IPC uplift between two specific architectures, you should divide rather than subtract. For example, the IPC difference between AMD’s Zen and Intel’s Skylake architectures is 5.664% (207.937 ÷ 196.825), and not 11.112% (207.937 − 196.825).

Generational instructions-per-clock uplift, relative to AMD Bulldozer.

The graphs have now been updated to include the recently launched Intel Core i7-8700K. Furthermore, for the sake of obtaining more accurate data for results against Coffee Lake’s predecessors, we decided to include all mainstream tier Intel Core i7 products dating back to Sandy Bridge in 2011.

The Core i7-8700K now dethrones the previous single-thread champion, the Core i7-7700K, predominantly with sheer core frequency improvements. An underclock to 3.00 GHz reveals very similar numbers to the chip it replaces; the only variable being more last-level cache for that single-threaded performance.

The newly launched AMD Ryzen 7 2700X has now been added to the graphs.

Paired with an X470 motherboard and system memory running at 2,933 MT/s, the second-generation Ryzen 7 processor shows an adequate clock-for-clock improvement of 4% over the initial Zen architecture from last year. However, the new iterations of AMD’s Precision Boost and Extended Frequency Range technologies, which now apply to all threads of the chip, are sure to bring some much larger gains in multi-threaded workloads. Zen’s unique architectural design means that you’ll see even greater numbers still with faster system memory than what was tested, and this applies to both generations.

The graphs have been updated, following the release of AMD’s second-generation Ryzen Threadripper processors.

Again, system memory is running at 2,933 MT/s. Out of the box, the new Threadripper models appear to have no problem matching Intel’s Skylake and Kaby Lake offerings. With AMD Precision Boost Overdrive technology working its magic, the 16-core 2950X shows off some seriously strong single-threaded performance. Its 32-core sibling demonstrates equally impressive numbers, albeit a little lower due to the frequency deficit.

As with the second-generation AM4-based Ryzen processors, AMD Precision Boost 2.0 technology can actually apply to all cores if given the conditions to do so. That’s some serious horsepower for a content creation machine.

AMD’s brand-new third-generation Ryzen processors have now been released, which means it’s time to update these graphs once again.

What happens when you take an already-strong floating-point unit design, and make it even stronger? Here’s your answer. Even with DDR4-3200 system memory, it’s a very strong showing for AMD. While Intel may still have the single-threaded performance advantage here, thanks to those very high frequencies, a combination of faster system memory and future Windows patches from Microsoft will certainly help to close that gap.

Zen 2 introduces a much stronger memory controller, now situated within the I/O chiplet of the package. AMD suggests to keep the memory controller in a 1:1 ratio between it and the Infinity Fabric; the underlying interconnect by which the processor as a whole communicates to other parts of the package. A 1:1 ratio is maintained with system memory up to DDR4-3733, before it falls back to the older 2:1 ratio of previous generations. For latency-sensitive workloads such as gaming, you’ll definitely want to keep that ratio at 1:1, but other workloads may prefer the additional memory bandwidth offered by faster system memory.

On a final note, we conducted some game stream testing using OBS at 1080p (1920 × 1080) resolution and found that when games were forced to occupy threads only within the same core complex, minimum frame rates were considerably better for both processors, beating out even the Intel Core i9-9900K by almost 25% on average, and sitting comfortably above 60 frames per second on a more consistent basis. That may be important for those of you looking to simultaneously play and stream your games.

Related content referenced in this article can be found below.

• AMD A10-6800K; desktop microprocessor
• AMD A10-7890K; desktop microprocessor
• AMD A12-9800; desktop microprocessor
• AMD FX-8150; desktop microprocessor
• AMD FX-8350; desktop microprocessor
• AMD Ryzen 7 1800X; desktop microprocessor
• AMD Ryzen 7 2700X; desktop microprocessor
• AMD Ryzen 7 3700X; desktop microprocessor
• AMD Ryzen 9 3900X; desktop microprocessor
• AMD Ryzen Threadripper 1950X; desktop microprocessor
• AMD Ryzen Threadripper 2950X; desktop microprocessor
• AMD Ryzen Threadripper 2990WX; desktop microprocessor
• Intel Core i7-2600K; desktop microprocessor
• Intel Core i7-3770K; desktop microprocessor
• Intel Core i7-3960X Extreme Edition; desktop microprocessor
• Intel Core i7-4770K; desktop microprocessor
• Intel Core i7-4960X Extreme Edition; desktop microprocessor
• Intel Core i7-5775C; desktop microprocessor
• Intel Core i7-5960X Extreme Edition; desktop microprocessor
• Intel Core i7-6700K; desktop microprocessor
• Intel Core i7-6900K; desktop microprocessor
• Intel Core i7-7700K; desktop microprocessor
• Intel Core i7-8700K; desktop microprocessor
• Intel Core i9-7900X; desktop microprocessor
• Intel Core i9-9900K; desktop microprocessor
• Intel Core i9-9900X; desktop microprocessor

Processors for smartphones, comparison, table

A mobile processor is a central computing element that is responsible for the performance of smartphones and other gadgets. It is one of the most important elements of a smartphone.

This type of processor is specially designed for mobile phones as well as tablets and laptops. And of course, different from those designed for PC.

Contents

1. What you need to know about mobile processors
2. Tasks performed by a mobile processor
3. Most important characteristics — how to understand them
4. Number of cores
5. Architecture
6. Process and cache
7. Memory levels middle price segment
8. The best budget options

What you need to know about mobile processors

This type of processor is designed to process processes and perform specified tasks by the gadget user. It is worth noting that this is a full-fledged single-chip system, which consists of a CPU (the main part of the processor that executes machine instructions), wireless communication modules, a graphics core and other components.

In most cases, it already has a video chip and many other sensors. The power of the processor is determined in clock frequency (GHz), and the more transistors applied, the higher the clock frequency of the processor will be.

Tasks performed by the mobile processor

The mobile processor has a number of tasks for which it is responsible:

1. UMTS/WLAN required to connect the device to the Internet;
2. USB controller;
3. Bluetooth;
4. Card reader;
5. Chamber;
6. HDMI.

Without a mobile processor, all these important elements cannot work.

The most important characteristics — how to understand them

When it comes to choosing a smartphone, you should always compare their characteristics with each other. Especially if the priority when choosing is given to a faster and sharper gadget. In this case, you need to look at the characteristics of mobile processors, some of the most important ones that you should pay attention to:

• Manufacturer;
• Number of cores;
• Clock frequency;
• Graphics core;
• Integrated cache;
• Number of threads;
• Energy saving.

Taking into account all these characteristics, it will be possible to choose a smartphone that is most suitable for the requirements of the future user and will not upset the buyer after purchase. Manufacturers and sellers of gadgets often provide convenient tables on their websites with the characteristics of the gadgets they sell.

Interesting! In today’s market, the most famous manufacturers that are responsible for almost 100% of the production of electronic chips are called Intel and AMD.

Number of cores

The core is a part of the microprocessor where arithmetic and logical operations are performed, and all device information is processed. The largest number of cores that can be in a mobile processor is ten.

Processors with two or more cores were invented so that the smartphone could not overheat from prolonged operation, and the chip would not fail. Several cores among themselves distribute the entire load on the processor and reduce heat dissipation. Therefore, the number of cores in a mobile processor plays an important role.

If the processor has at least two cores, then even more transistors can be connected to increase the power and speed of the smartphone, as well as reduce heat dissipation, which will affect the heating rate of the device.

Many people are of the opinion that “the more the better”, without understanding this issue. In fact, this opinion is fundamentally erroneous.

Most mobile applications today are single-threaded and use only one core to run. In very rare cases, two cores are used.

Multi-core processors are needed only in cases where the smartphone is bought for heavy games that give a sufficiently high load on the processor, then at least four cores are launched simultaneously. Such games can be counted on one hand, because developers are trying to reduce the power of games so that even the weakest devices can handle it, as this will increase the number of sales.

Architecture

Processor architecture is a combination of the main principles of its design, the general layout of parts on a silicon chip and the scheme of interaction between software and a chip. In short, we can say that this is a diagram of how the processor works. The architecture works sequentially, moving from one stage to the next. Moreover, the number of such stages can be completely different.

The most popular architectures are:

1. MISC;
2. VLIW;
3. CISC;
4. RISC.

RISC and CISC are currently in the most active use. The differences between all these architectures are the systems of interaction of the processor with the main data of the gadget.

Process and cache

Process is the size of the transistors used. Accordingly, the thinner the transistor process technology, the more transistors can be distributed on a chip, and, consequently, the processor performance will be higher. The process technology affects the number of active elements of a semiconductor system.

Cache — memory with ultra-fast data transfer speed, or in other words — this is one of the components of the processor that affects the speed of the smartphone, consists of a set of records. In this case, each entry is associated with a small piece of data (block) or some one data element, which is a copy of the information element in the main memory.

Also, each entry has its own identifier, which is responsible for the correspondence between data elements in the cache and their copies in the main memory of the device.

Interesting! For the past half century, a silicon crystal has been used to manufacture the processor.

Memory levels

Currently, most modern processors have several cache levels:

• L1;
• L2;
• L3.

The first level is responsible for fast access to the processor core, while it operates at the same frequencies as the processor. The second level connects the first level with the third. The third has the slowest access speed, because it drops with each level, but its speed is more productive, and it is designed for the entire processor.

Flagship processors — the best of the best for the most demanding

The top 10 processors are mainly chipsets created and developed by Apple, as well as processors used for Android smartphones:

1. Qualcomm;
2. Samsung;
3. MediaTek;
4. HiSilicon;
5. Google.

The processes released by these companies are considered the flagships of the modern market today. Basically, the number of cores of these processors starts with six and ends with eight.

Rating of processors from the middle price segment

In the rating of processors of the middle price segment there are also the best ones that can suit the demanding buyer. It is worth paying attention to the following Qualcomm models:

• Snapdragon 780G;
• Snapdragon 768G, 765, 765G;
• Snapdragon 750G;
• Snapdragon 730, 730G, 732G;
• Snapdragon 710, 712, 720G.

The above models belong to the upper middle price segment, are included in the top. You can also stop at chipsets produced by MediaTek and Samsung:

• MediaTek Dimensity 1000;
• MediaTek Dimensity 800;
• MediaTek Dimensity 700;
• Exynos 980;
• Exynos 1080;
• Exynos 9609, 9610.

These processors belong to the usual middle price segment. When choosing a smartphone at an average price, you can pay attention to those devices that have processors from the selection above.

The best budget options

For those who do not want to save money on buying a smartphone, but at the same time get a high-quality and modern device, you need to carefully look at its characteristics so as not to make a mistake in your choice. Smartphones of this category are designed for more budget processors. Some of the best are produced by Qualcomm:

• Snapdragon 690;
• Snapdragon 675, 670, 678;
• Snapdragon 662.

These are budget chipset options, but some of them are equipped with 8nm or 11nm process technology, which are quite powerful compared to others used for a low-end device. But in general, devices that contain entry-level processors operate at a frequency of only 500 to 800 GHz.

Smartphone with a powerful processor can be found on the market in any price segment. Even budget models that almost everyone can afford are equipped with quite good processors that can run a large number of games and perform many other functions.

Therefore, in order to choose the right device that best suits the requirements and goals of the user, you should always pay attention to the characteristics of the phone and choose between them the most suitable option.

How do you like the article?

All Mediatek processors for 2022 — characteristics, comparison with Qualcomm, examples of smartphones Yes, it is still lagging behind market leader Qualcomm, yes, its market leadership is in the volume of chips shipped, not in revenue, where the competitor takes almost half the profits in the industry, but it continues to release not only budget chips , but dares to compete with the giants in the market for high-performance solutions.

The Dimensity line conquers smartphone manufacturers and they do not hesitate to release their flagships based on solutions from Mediatek, which already says a lot! Let us consider in detail the processors that were released from 2020 to 2022, select their analogues in the Qualcomm camp and give examples on which smartphones you can meet them.

See also Qualcomm 2022 processor overview

Helio Gxx line briefly

In 2020-2021, the media library continued the Helio G line with a dozen new chips from Helio G25 to Helio G99. These are all 8-core processors made according to the 12nm process technology with LPDDR4x memory. Nothing impressive, but still among them there are worthy candidates for the mainstream segment. The younger models use 8 Cortex-A53 cores in two 4 + 4 clusters with a slight difference in frequency. They show very modest results in tests no higher than 130 thousand points in antutu, so they can only be found in budget solutions, for example, Xiaomi Redmi 10A, Realme C20 and Tecno smartphones. Qualcom has only one analogue — Snapdragon 460.

The middle category Helio G70, G80, G85 and G88 are already built according to the 2 + 6 core scheme and the reference ARM Cortex-A75 is used in the upper cluster. Mali G52 graphics appear, albeit with only two cores, and an LTE Cat7 modem is used with download speeds up to 300Mbps. Tests show from 194 thousand. up to 238 thousand antutu points. These processors can already be found in the younger Samsungs — A32 and M32, in the budget Xiaomi Redmi 9 and the endless range of Tecno and Infinix. An analogue can be called Snapdragon 680.

The high-end G95, G96 and G99 already use Cortex-A76 cores, Mali G76 quad-core graphics and LTE Cat12 modems with download speeds up to 600Mbps. Antutu pleases with numbers from 307 thousand. up to 355 thousand points, which is adequate to compare with Snapdragon 732G and 750G chips. The processors are found in Realme 7 and 8 models, Poco M4 Pro and Xiaomi Redmi Note 11 Pro. Mediatek Dimensity 2020

Not all of them fully entered the market, but that’s why it is a media library in order to promise a lot and fulfill a little less.

Dimensity 720, 800, 800U and 820 are based on Cortex-A76 cores, use Mali-G57 graphics and LPDDR4X memory. They also have a 5G modem with download speeds up to 4.7Gbps. Antutu tests show from 289 thousand. up to 415 thousand points on these processors, which can be compared with Qualcom Snapdragon 720G, 732G and 750G chips.

Dimensity 1000 was promised in four versions — 1000, 1000+, 1000L and 1000C, but only 1000 and 1000C appeared on the market, the latter only in the USA. This system includes Cortex-A77 cores and Mali-G77 graphics, also with a 5G modem, but with slightly reduced memory running at 1866MHz. Test scores are about 520,000. Antutu points, which puts them on a par with the Snapdragon 778G. Realme X7 Pro, Xiaomi Redmi K30 Ultra and several other models came out on the chip.

Mediatek Dimensity 2021

Believing in itself, Mediatek decided to continue and develop the Dimensity line. In 2021, 6 new chips were released within its framework. There was a transition to the 6nm TSMC N6 process technology and new graphics appeared.

Dimensity 700 and 810 became the youngest in the series. They were equipped with a set of 2 + 6 cores with Cortex-A76 at the head and dual-core Mali-G57 graphics. Tests showed 258 thousand. and 385 thousand. respectively, which almost completely repeats the results of the Snapdragon 480 and 480+ chips. Smartphones such as Xiaomi Redmi Note 10, Poco M4, Realme 8 and Samsung Galaxy A13 and M13 came out on processors. All of them with the prefix 5G, to distinguish from previous models in the series.

Dimensity 900 and 920 stuck in a small gap between the 800 and 1000 series. They had the same core structure, but the updated Mali-G68 GPU already had 4 graphics cores. This made it possible to show in tests 476 thousand. and 497 thousand. Antutu points, which puts them slightly higher than the Snapdragon 768G counterpart.

The Dimenity 1100 offered an outdated 4+4 core scheme but with new Cortex-A78 cores in the top cluster. But Dimensity 1200 for the first time in a media library uses a three-cluster big-midl-little structure. It includes 1 Cortex-A78 core at 3GHz, three Cortex-A78 cores at 2.6GHz, and a lower cluster of 4 Cortex-A55 cores at 2GHz. Graphics in both chips updated to Mali-G77 from 9cores. The increase in tests was not long in coming and the indicators reached the level of 609 thousand. and 720 thousand. Antutu points, which almost equaled the results of the competitors’ flagship Snapdragon 870. The processors were installed in OnePlus Nord 2, Xiaomi 11T, Xiaomi Redmi Note 10 Pro and Poco X3 GT smartphones.

Mediatek Dimensity 2022

While Qualcomm has been focusing on the high-performance chips segment, Mediatek has been filling all the vacant niches and in 2022 offered the market as many as 7 new chips in three main categories: budget, mid-range and flagships. These are all 8-core solutions with support for 5G networks, but inside they are very different.

Dimensity 930 alone continues the younger series. It, like the previous 9xx chips, has a 2 + 6 core structure, in the upper cluster of which the already outdated Cortex-A76 is used. Not the most common IMG BXM-8-256 chip was taken as the GPU, which has not been seen either earlier or later. The upgrade did not work out: in tests, the new product shows exactly the same result as its last year’s revision Dimensity 920 — 497 thousand rubles. antutu points. The analogue is Snapdragon 695. So far, there is only one smartphone model on the market on this chip — Vivo Y77, but it’s not over yet, someone will definitely release a dozen more.

The Dimensity 1050 uses the same 2+6 layout, but the older cores have been upgraded to Cortex-A78 with a boost to 2500MHz. The graphics are new Mali-G610, but with only 3 cores, a fairly budget option. The chip is fresh, no smartphones have yet been released on it, and therefore there is no reliable data on the tests. I suppose you can expect similar performance to the Dimensity 930 and about 500k. points in antutu.

Dimensity 1300 completely repeats the characteristics of last year’s 1200 and received an update only in the program code. It released smartphones Oppo Reno 8 and Vivo T2X, test results are similar to Dimensity 1200.

And then new items: Dimensity 8000 and 8100 is a transition to a thinner 5nm process technology, and therefore an increase in frequency to 2.75GHz and 2.85GHz, respectively. Updated graphics, GPU ARM Mali-G610 with 6 cores is used. The memory subsystem received LPDDR5 with a frequency of 3200 MHz. The upgrade had a positive impact on the tests: Dimensity 8000 is gaining 801 thousand. points in antutu, and Dimensity 8100 shows 822 thousand. points, which is very close to Snapdragon 888. These chips can be found in smartphones Honor 70 Pro, OnePlus 10R, Oppo K10 5G, Oppo Reno8 Pro, Poco X4 GT, Realme GT Neo 3, Xiaomi Redmi K50, Xiaomi Redmi Note 11T Pro and Xiaomi Redmi Note 12 Pro

The flagship media library at the moment is a couple of Dimensity 9000 and 9000+. Everything is in the latest fashion here: 4nm process technology from TSMC, 1 + 3 + 4 core layout, where the newfangled Cortex-X2 is in the upper cluster, and the new Cortex-A710 and A510 are also in the middle and lower clusters. 3050 and 3200MHz frequencies, 10-core Mali-G710 graphics, 3750MHz LPDDR5x memory and a new 5G modem. It is no wonder that in tests it almost does not lag behind Snapdragon 8 Gen.1 and gives out more than a million antutu points (1,049,081 for Dimensity 9000 and 1,080,000 for 9000+). Honor 70 Pro +, Oppo Find X5 Pro, Vivo X80 and Xiaomi 12 Pro have already been released on chips.

Mediatek Dimensity in 2023

What can we expect from Mediatek next year? Breaking into the market of flagship chips, Taiwan will try to consolidate its positions there, so we should expect Dimensity 9100 with slightly increased frequencies and finished software, which will give a slight increase in tests, but greater stability in operation.

Undoubtedly, the media library will continue its junior lines. Can expect Dimensity 940, 1400 and 8200 with various variations of the Cortex-A710 and A510 cores.

Whether the Helio G line for budget smartphones will continue is a difficult question. This market segment is actively torn off by the manufacturer Unisoc and perhaps Mediatek has already lost interest in it.

Given the global shortage of chips and the brewing conflict between China and Taiwan, it is more profitable for the manufacturer to invest in more expensive technologies and abandon budget solutions. It is possible that in 2023 Mediatek will follow the path of Qualcom and abandon a wide range of processors of different price categories in favor of three or four flagship chips.

We will learn more about Mediatek’s plans at CES 2023, which usually takes place in the first days of the new year.

All mobile processors for 2022 table

Data for all mobile processors currently on the market are collected in a table.
You can download the table and use it as you wish.