Screen size
Diagonal of the screen installed in a monoblock (see "Type").
In general, the larger the diagonal, the more advanced both the screen and the computer as a whole are considered. The large display size is convenient for games, movies, and some special tasks like layout of large printed materials; in addition, a higher resolution can be provided for such a screen, and more space is available inside the case for advanced components. On the other hand, a larger monoblock will cost much more than a relatively small one, even if the other characteristics of such models are completely the same. In addition, the power of the hardware is not directly related to the size of the screen — high-end monoblocks can be quite small.
As for specific numbers, a
diagonal of 20" or less is considered very limited nowadays,
monoblocks of 21.5" are small,
a 24" screen is medium, and values of
27" and
32" indicate large sizes.
Panel type
The type of matrix used in the monoblock screen (see "Type").
—
TN+film. The simplest and most inexpensive type of modern matrices. In addition to low cost, the advantages of TN + Film include good speed (short response time). But the overall picture quality can be described as average: in terms of brightness, colour gamut and colour reproduction quality, screens of this type are noticeably inferior to more advanced options. However this quality is quite enough for relatively simple tasks like surfing the web or working with documents, and in most cases even for playing games and watching movies; however, TN-Film screens are not suitable for professional work with colour.
—
IPS. A variety of matrices designed for high image quality. In terms of brightness and colour fidelity, such screens are indeed far superior to TN-film, making them excellent for professional use. In addition, these properties are valued among demanding gamers and movie fans. The response time in early versions of IPS screens was quite high, but in modern versions this feature is almost eliminated. But the unequivocal disadvantage of such screens is the rather high cost. Also note that nowadays on the market there are several varieties of IPS, differing in characteristics. For example, E-IPS is a relatively simple and inexpensive option, P-IPS and H-IPS are professional (when they were created, maximum attention was
...paid to colour reproduction), and AH-IPS was developed with an eye on ultra-high resolution screens. So it would not hurt to clarify the specific features of such a screen separately — especially if a monoblock is bought for design, photo processing and other similar tasks that involve careful work with colour.
— pls. In fact, one of the versions of the IPS technology described above, created by Samsung. During development, special attention was paid to both improving performance and reducing the cost of the matrix; in the end, according to the creators, they really managed to achieve higher brightness and contrast, combined with a lower cost. In general, the characteristics are comparable to mid-level versions of IPS.
— *VA. Various versions of VA technology — Fujitsu's MVA, Samsung's PVA and Super PVA, Sharp's ASVA, etc.; In general, there are no key differences in design between these versions. The *VA technology itself was created as a compromise between the speed and affordability of TN-Film matrices and the high-quality "picture" of IPS. The result is screens with more accurate and complete colour reproduction than TN, with good blacks and good viewing angles; the response speed was initially not very high, but in modern versions this drawback has been practically eliminated. At the same time, a feature of *VA screens is that the colour balance of the visible image depends on the viewing angle and changes with the slightest deviation from the perpendicular. With normal PC use, this phenomenon is almost imperceptible, however, such monitors are still poorly suited for professional work with colour.Surface treatment
Type of own screen cover in monoblock (see "Type").
—
Glossy. The most common type of coating in modern PCs. Such a surface (with the same characteristics of the matrix) noticeably surpasses the matte one in terms of brightness and colour saturation in the visible image. The main disadvantage of gloss is the tendency to glare in bright ambient light; however, all-in-one PCs are not often used in such conditions, and this phenomenon can be compensated by increasing the brightness of the backlight. With all this, this type of coverage is quite inexpensive.
—
Glossy (anti-glare). A modified version of the glossy finish (see above) that, as the name suggests, is more resistant to glare. At the same time, in terms of picture quality, such screens are usually not inferior to classic gloss. On the other hand, the anti-reflective surface is somewhat more expensive, and its advantages in this case are not often really significant. Therefore, screens with such a coating are found in modern monoblocks much less often than glossy ones.
—
Matte. The key advantages of a matte finish are its low cost and the almost complete absence of glare, even in bright ambient light. On the other hand, the image on such a screen is dimmer than on glossy displays (including anti-glare) with similar matrix characteristics. Therefore, this type of coating is rarely used
...nowadays — mainly in relatively inexpensive household and business models, for which a bright picture with saturated colours is not fundamental.Passmark CPU Mark
The result shown by the PC processor in the test (benchmark) Passmark CPU Mark.
Passmark CPU Mark is a comprehensive test that allows you to evaluate CPU performance in various modes and with a different number of processed threads. The results are displayed in points; the more points, the higher the overall performance of the processor. For comparison: as of 2020, in low-cost solutions, the results are measured in hundreds of points, in mid-range models they range from 800 – 900 to more than 6,000 points, and individual top-end chips are capable of showing 40,000 points or more.
Geekbench 4
The result shown by the PC processor in the test (benchmark) Geekbench 4.
Geekbench 4 is a comprehensive cross-platform test that allows, among other things, to determine the efficiency of the processor in various modes. At the same time, according to the developers, the verification modes are as close as possible to various real tasks that the processor has to solve. The result is indicated in points: the more points — the more powerful the CPU, while the difference in numbers corresponds to the actual difference in performance ("twice the result — twice the power").
Note that the benchmark in Geekbench 4 is the Intel Core i7-6600U processor with a clock frequency of 2.6 GHz. Its power is estimated at 4000 points, and the performance of other tested CPUs is already compared with it.
Cinebench R15
The result shown by the PC processor in the test (benchmark) Cinebench R15.
Cinebench is a test designed to test the capabilities of the processor and graphics card. The creator of this benchmark, Maxon, is also known as the developer of the Cinema 4D 3D editor; this determined the features of testing. So, in addition to purely mathematical tasks, when using Cinebench R15, the processor is loaded with processing high-quality three-dimensional graphics. Another interesting feature is the extensive support for multithreading — the test allows you to fully check the power of chips that process up to 256 threads at a time.
Traditionally, for CPU benchmarks, the test results are indicated in points (more precisely, points — PTS). The more points scored by the CPU, the higher its performance.
3DMark
The result shown by the PC graphics card in the 3DMark test (benchmark).
3DMark is a specialized test designed primarily to test the performance and stability of a graphics card in demanding games. The verification is carried out by running 3D videos created on various game engines using various technologies. The final result is evaluated both in terms of frame rate and in conditional points; in this paragraph, just the number of points is given. The higher it is, the more powerful and performant the graphics card is.
Note that 3DMark testing can be carried out for any type of graphics (see "Graphics card type"). At the same time (as of 2020) in integrated solutions, the final result rarely exceeds 1000 points; the most modest indicator for discrete adapters is about 1700 points; and in some high-end graphics cards, it can exceed 10,000 points.
Passmark G3D Mark
The result shown by the PC graphics card in the test (benchmark) Passmark G3D Mark.
Passmark G3D Mark is a comprehensive test to check the performance of a graphics card in various modes. Traditionally for such tests results are displayed in points, more points mean (proportionately) higher computing power. However, note that the graphics card is tested in different modes, and the final score is derived based on several results in specialized tests. Therefore, adapters with a similar overall result may differ slightly in actual performance in certain specific formats of operation. So if a PC is purchased for professional work with graphics, and high efficiency in some specialized tasks is critical, it will not hurt to clarify these nuances separately.
Note that with the help of Passmark G3D Mark, nowadays, all types of graphics adapters are tested (see "Graphics card type"). At the same time, for integrated solutions, a result of more than 1200 points is considered very good, and in discrete models this figure can vary from 2200 – 2300 points to 20,000 points or more.
Drive type
The type of storage device that is installed in the computer.
Note that many PCs allow you to add a complete drive or even completely replace it, but it is more convenient to buy a suitable configuration initially and not bother with re-equipment. In terms of types, traditional hard disk drives (
HDD) are increasingly losing ground to
SSD solid-state modules nowadays. In addition,
HDD + SSD combinations are quite popular (including those using advanced
Intel Optane and
Fusion Drive technologies). But solutions such as SSHD and eMMC have practically fallen into disuse. Let's take a closer look at these options:
— HDD. Classic hard disk. The key advantage of such drives is their low cost per unit of volume — this allows you to create capacious and at the same time inexpensive storage. On the other hand, HDDs are noticeably inferior to SSDs in terms of speed, and they also do not tolerate shocks and shocks. Thus, this type of media is less and less used in its pure form — it is much more common to find a combination of a hard drive with an SSD module (see below).
— SSD. Solid state drives based on flash memory. With the same volume, an SSD is much more expensive than an HDD, but this is justified by a number of advantages. First, such drives are much faster than hard drives; specif
...ic performance may be different (depending on the type of memory, connection interface, etc.), however, even inexpensive SSDs outperform advanced HDDs in this indicator. Secondly, solid-state memory has no moving parts, which offers several advantages at once: lightness, compactness, shock insensitivity and low power consumption. And the cost of such memory is constantly decreasing as technology advances. So more and more modern PCs are equipped with just such drives, and these can be configurations of any level — from low-cost to top ones.
— HDD+SSD. The presence in one system of two drives at once — HDD and SSD. Each of these varieties is described in more detail above; and their combination in one system allows you to combine the advantages and partially compensate for the shortcomings. For example, an SSD (which usually has a fairly small capacity) can store system files and other data for which speed of access is important (for example, work applications); and HDD is well suited for large volumes of information that do not require particularly high speed (a typical case is video files and other multimedia content). In addition, the solid-state module can be used not as a separate storage, but as an intermediate cache to speed up the hard drive; however, this usually requires special software settings (whereas the "two separate drives" mode is most often available by default).
We also emphasize that in this case we are talking about “ordinary” SSD modules that do not belong to the Optane and Fusion Drive series; the features of these series are detailed below.
HDD + Optane. Combination of a traditional hard drive with an Intel Optane series SSD. For more information about the general features of this combination, see "HDD + SSD" above. Here, we note that “optains” differ from other SSD drives in a special three-dimensional structure of memory cells (3D Xpoint technology). This allows you to access data at the level of individual cells and do without some additional operations, which speeds up the speed and reduces latency, and also has a positive effect on memory life. The second difference is that Optane is usually used not as a separate drive, but as an auxiliary buffer (cache) for the main hard drive, designed to increase speed. Both drives are perceived by the system as a single device. The disadvantage of this type of SSD is traditional — a rather high cost; it is also worth noting that its superiority is most noticeable at relatively low loads (although it does not disappear completely with increasing load).
— HDD + Fusion Drive. A kind of HDD + SSD bundle (see above), used exclusively in Apple computers and optimized for the proprietary macOS operating system. However, it would be more correct to compare this option with the “HDD + Optane” combination (also described above): for example, both drives are perceived by the system as a single unit, and the Fusion Drive module is also used as a high-speed cache for the hard drive. However, there are also significant differences. Firstly, Fusion Drive has significant volumes and is used not only as a service buffer, but also as part of a full-fledged drive — for permanent data storage. Secondly, the total volume of the entire bundle approximately corresponds to the sum of the volumes of both drives (minus a couple of "service" gigabytes). This type of drive is expensive, but the efficiency and convenience are well worth the price.
— SSHD. The so-called hybrid drive: a device that combines a hard drive and a small SSD cache in one case. Some time ago, this solution was quite popular, but now it is almost never found, having been supplanted by a more practical option — various types of HDD + SSD.
— eMMC. A type of solid-state memory originally developed for portable gadgets such as smartphones and tablets. It differs from SSD, on the one hand, in lower cost and low power consumption, on the other hand, in relatively low speed and reliability. Because of this, this type of drive is used extremely rarely — in particular, in single models of microcomputers and thin clients (see "Type").
— HDD + eMMC. Combination of hard disk drive (HDD) and eMMC solid state module. These types of drives are described in detail above; here we note that this option is extremely rare, and in rather specific devices — monoblocks (see "Type") with a transformer function, where the screen is a removable tablet that can be used autonomously. In such a tablet, an eMMC module is usually installed, and a hard drive is placed in the stationary part. However, another option is also possible — a bundle similar to HDD + SSD (see above), where eMMC is used to reduce cost and/or power consumption.
— SSD + eMMC. Another combination of the two types of drives described above. It was used in single monoblocks and nettops — mainly to reduce the cost; Today, this variant is almost non-existent.