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Comparison Gigabyte GA-AX370-Gaming K5 vs Gigabyte GA-AX370-Gaming 5

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Gigabyte GA-AX370-Gaming K5
Gigabyte GA-AX370-Gaming 5
Gigabyte GA-AX370-Gaming K5Gigabyte GA-AX370-Gaming 5
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Featuresgaming for overclockinggaming for overclocking
SocketAMD AM4AMD AM4
Form factorATXATX
Power phases710
VRM heatsink
LED lighting
Lighting syncGigabyte RGB FusionGigabyte RGB Fusion
Size (HxW)305x244 mm305x244 mm
Chipset
ChipsetAMD X370AMD X370
BIOSAmiAmi
DualBIOS
UEFI BIOS
RAM
DDR44 slot(s)4 slot(s)
Memory moduleDIMMDIMM
Operation mode2 channel2 channel
Max. clock frequency3200 MHz3200 MHz
Max. memory64 GB64 GB
XMP
Drive interface
SATA 3 (6Gbps)88
M.2 connector11
M.21xSATA/PCI-E 4x1xSATA/PCI-E 4x
U.2 connector1
Integrated RAID controller
Expansion slots
1x PCI-E slots33
PCI-E 4x slots1
PCI-E 8x slots1
PCI-E 16x slots13
PCI Modes16x/0x/4x, 8x/8x/4x
PCI Express3.03.0
Steel PCI-E connectors
Internal connections
USB 2.02
USB 3.2 gen12
Video outputs
HDMI output
Integrated audio
AudiochipRealtek ALC1220Realtek ALC1220
Sound (channels)7.17.1
Optical S/P-DIF
Network interfaces
LAN (RJ-45)1 Gbps1 Gbps
LAN ports12
LAN controllerIntel GbEKiller E2500
External connections
USB 3.2 gen16
USB 3.2 gen293
USB C 3.2 gen21
PS/211
Power connectors
Main power socket24 pin24 pin
CPU power8 pin8 pin
Fan power connectors58
Added to E-Catalogmarch 2017february 2017

Power phases

The number of processor power phases provided on the motherboard.

Very simplistically, phases can be described as electronic blocks of a special design, through which power is supplied to the processor. The task of such blocks is to optimize this power, in particular, to minimize power surges when the load on the processor changes. In general, the more phases, the lower the load on each of them, the more stable the power supply and the more durable the electronics of the board. And the more powerful the CPU and the more cores it has, the more phases it needs; this number increases even more if the processor is planned to be overclocked. For example, for a conventional quad-core chip, only four phases are often enough, and for an overclocked one, at least eight may be needed. It is because of this that powerful processors can have problems when used on inexpensive low-phase motherboards.

Detailed recommendations on choosing the number of phases for specific CPU series and models can be found in special sources (including the documentation for CPU itself). Here we note that with numerous phases on the motherboard (more than 8), some of them can be virtual. To do this, real electronic blocks are supplemented with doublers or even triplers, which, formally, increases the number of phases: for example, 12 claimed phases can represent 6 physical blocks with doublers. However, virtual phases are much inferior to real ones in terms of capabilities — in fact, t...hey are just additions that slightly improve the characteristics of real phases. So, let's say, in our example, it is more correct to speak not about twelve, but only about six (though improved) phases. These nuances must be specified when choosing a motherboard.

XMP

The ability of the motherboard to work with RAM modules that support XMP (Extreme Memory Profiles) technology. This technology was developed by Intel; it is used in motherboards and RAM blocks and only works if both of these system components are XMP compliant. A similar technology from AMD is called AMP.

The main function of XMP is to facilitate system overclocking (“overclocking”): special overclocking profiles are “sewn” into the memory with this technology, and if desired, the user can only select one of these profiles without resorting to complex configuration procedures. This is not only easier, but also safer: every profile added to the bar is tested for stability.

U.2 connector

The number of U.2 connectors provided in the design of the motherboard.

U.2 is a specialized connector for connecting internal drives — primarily modern SSD modules that support high-speed NVMe data transfer technology. Such an interface can support up to 4 PCI-E lanes (see PCI-E 4x slots) and up to 2 SATA 3 lanes (see above). Note that in fact, U.2 is mainly used in 2.5" form factor drives installed in case slots and connected to the board with a cable. Due to their large size, such drives generally become more capacious than M.2 modules. (see above).

PCI-E 4x slots

Number of PCI-E (PCI-Express) 4x slots installed on the motherboard.

The PCI Express bus is used to connect various expansion cards — network and sound cards, video adapters, TV tuners and even SSD drives. The number in the name indicates the number of PCI-E lines (data transfer channels) supported by this slot; the more lines, the higher the throughput. 4 PCI-E lanes provide data transfer speeds of about 4 GB/s for PCI-E version 3.0 and 8 GB/s for version 4.0 (for more information about the versions, see "PCI Express Support").

The general rule for PCI-E is this: the card must be connected to a slot with the same or more lanes. Thus, boards for 1 or 4 PCI Express lanes can be installed in a standard PCI-E 4x slot. However, it is worth noting that in the design of modern "motherboards" there are slots of increased sizes — in particular, PCI-E 4x, corresponding in size to PCI-E 16x. The type of such slots in our catalog is indicated by the actual throughput, that is, the mentioned example will also be counted as PCI-E 4x. At the same time, peripherals with 16 PCI-E channels can also be physically connected to this connector — however, you should make sure that the throughput will be sufficient for the normal operation of such peripherals.

PCI-E 8x slots

The number of PCI-E 8x slots installed on the motherboard. This is an eight-lane version of the PCI-Express connection bus, with a minimum throughput of 16 Gbps one way (32 Gbps both). For more information about the PCI-Express standard, see "PCI-E 1x Slots".

PCI-E 16x slots

Number of PCI-E (PCI-Express) 16x slots installed on the motherboard.

The PCI Express bus is used to connect various expansion cards — network and sound cards, video adapters, TV tuners and even SSD drives. The number in the name indicates the number of PCI-E lines (data transfer channels) supported by this slot; the more lines, the higher the throughput. 16 lanes is the largest number found in modern PCI Express slots and cards (more is technically possible, but the connectors would be too bulky). Accordingly, these slots are the fastest: they have a data transfer rate of 16 GB / s for PCI-E 3.0 and 32 GB / s for version 4.0 (for more information about the versions, see "PCI Express Support").

Separately, we note that it is PCI-E 16x that is considered the optimal connector for connecting video cards. However, when choosing a motherboard with several such slots, it is worth considering the PCI-E modes supported by it (see below). In addition, we recall that the PCI Express interface allows you to connect boards with a smaller number of lines to connectors with numerous lines. Thus, PCI-E 16x will fit any PCI Express card.

It is also worth mentioning that in the design of modern "motherboards" there are slots of increased sizes — in particular, PCI-E 4x, corresponding in size to PCI-E 16x. However, the type of PCI-E slots in our catalog is indicated by the actual throughput; so only connectors that support 16x speed are considered as PCI-E 16x.

PCI Modes

Operating modes of PCI-E 16x slots supported by the motherboard.

For more information about this interface, see above, and information about the modes is indicated if there are several PCI-E 16x slots on the board. This data specifies at what speed these slots can operate when expansion cards are connected to them at the same time, how many lines each of them can use. The fact is that the total number of PCI-Express lanes on any motherboard is limited, and they are usually not enough for the simultaneous operation of all 16-channel slots at full capacity. Accordingly, when working simultaneously, the speed inevitably has to be limited: for example, recording 16x / 4x / 4x means that the motherboard has three 16-channel slots, but if three video cards are connected to them at once, then the second and third slots will be able to give speed only to PCI-E 4x level. Accordingly, for a different number of slots and the number of digits will be appropriate. There are also boards with several modes — for example, 16x/0x/4 and 8x/8x/4x (0x means that the slot becomes inoperable altogether).

You have to pay attention to this parameter mainly when installing several video cards at the same time: in some cases (for example, when using SLI technology), for correct operation of video adapters, they must be connected to slots at the same speed.

Steel PCI-E connectors

The presence of reinforced steel PCI-E connectors on the "motherboard".

Such connectors are found mainly in gaming (see "In the direction") and other advanced varieties of motherboards, designed to use powerful graphics adapters. Steel slots are usually made PCI-E 16x, just designed for such video cards; in addition to the slot itself, its attachment to the board also has a reinforced design.

This feature offers two key advantages over traditional plastic connectors. Firstly, it allows you to install even large and heavy video cards as reliably as possible, without the risk of damaging the slot or board. Secondly, the metal connector plays the role of a protective screen and reduces the likelihood of interference; this is especially useful when using multiple video cards installed side by side.

USB 2.0

The number of USB 2.0 connectors provided on the motherboard.

USB connectors (all versions) are used to connect to the "motherboard" USB ports located on the front panel of the case. With a special cable, such a port is connected to the connector, while one connector, usually, works with only one port. In other words, the number of connectors on the motherboard corresponds to the maximum number of front USB connectors that can be used with it.

Specifically, USB 2.0 is the oldest version widely used nowadays. It provides data transfer rates up to 480 Mbps, is considered obsolete and is gradually being replaced by more advanced standards, primarily USB 3.2 gen1 (formerly USB 3.0). Nevertheless, a lot of peripherals are still being produced under the USB 2.0 connector: the capabilities of this interface are quite enough for most devices that do not require a high connection speed.
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