Features
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Ordinary. This category includes all sound cards that do not have a pronounced specialization and do not belong to any of the types described below. Usually, they have a set of characteristics of an entry-level or intermediate level and are designed for simple everyday tasks: listening to music and game sound through ordinary speakers or headphones, communicating on the Web through a microphone, etc. Conventional sound cards are equipped with both digital-to-analogue and analogue-to-digital converters, they can be either internal or external.
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Audiophile (Hi-Fi). Sound cards designed for lovers of high-quality sound; they can also be useful for professionals who are engaged in professional audio processing and need the most accurate reproduction of the received signal. Accordingly, models of this type are distinguished by high build quality, advanced components, as well as the presence of additional equipment, an abundance of interfaces and advanced customization options (both software and hardware, including even the ability to replace individual circuit components). However, these cards cost accordingly.
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Gamer's. Sound cards originally designed as components for advanced gaming systems. Accordingly, the main purpose of such models is high-quality transmission of game sound, including three-dimensional and multichannel. Typically, gaming audio ca
...rds are equipped with advanced DACs and support various special standards (see below); in addition, they may have additional equipment such as remote control modules (see below). The vast majority of models of this type are made internal, but they often have a rather original design (which is useful for modding enthusiasts who use transparent cases).
— CAP. Abbreviation for "Digital to Analogue Converter". Usually, this term refers to the constituent element of a sound card, but in this case it refers to a separate type of audio cards, the distinguishing feature of which is the absence of an analogue-to-digital converter (ADC). Accordingly, DACs are only capable of transmitting sound from a computer to headphones, speakers, etc., and cannot be used to digitize sound from a microphone or other external signal source. Note that this category includes a variety of models — from the simplest USB-headphone adapters, the size of a flash drive, to advanced audiophile-class solutions.
— Audio interface. A kind of opposite to the DAC described above: audio interfaces are designed primarily to digitize the sound coming to the input (for example, from a microphone or an electric guitar). Accordingly, they are not only necessarily equipped with analogue-to-digital converters — usually, these ADCs have very advanced characteristics and extensive sound tuning capabilities (and in some models even hardware switches are provided for this). At the same time, audio interfaces can also work in the digital-to-analogue audio conversion mode (in other words, to output sound to headphones/speakers). The cost of such devices is usually quite high, so it makes sense to purchase them only for those who plan to work a lot with sound recording.Interface
The main interface used to connect a sound card to a computer or other device.
Like the sound cards themselves, the interfaces used in them are divided into internal (
PCI,
PCI-E USB,
USB C,
FireWire, Thunderbolt, 3.5 mm mini-jack, Bluetooth). Here is a more detailed description of each of these options:
— PCI-E. The main modern interface for connecting internal peripherals (including sound cards) to computer motherboards. Used in most internal type models (see above). The main advantage of solutions with PCI-E is that connectors for their connection can be found on almost any modern motherboard. True, these connectors may be needed for other components - a video card, a TV tuner, or even an SSD drive; however, even on the simplest motherboards, there are usually several PCI-E slots, so this point cannot be called a serious drawback.
— PCI. Interface for connecting expansion boards to the PC motherboard. It is the forerunner of PCI-E, has significantly lower bandwidth and more limited features, so is generally obsolete. Nevertheless, in our time, motherboards with such connectors and sound cards for the PCI interface (including quite advanced ones) continue to be produced. This is due to the fact that a relatively low bandwidth
...is sufficient to work with sound; and installing an audio card in the PCI slot leaves PCI-E slots free, which may be required for components that are more demanding on connection speed. In any case, before buying such a sound card, it does not hurt to make sure that the "motherboard" has a connector for connecting it.
— USB. Connection via standard USB port. Until recently, this was the most popular interface for external peripherals, found in almost all PCs and laptops. It was under USB that most external sound cards were made. The disadvantage of this connection method is that USB connectors may be required for other devices, which creates problems with a small number of ports and an abundance of peripherals. On the other hand, such situations do not occur so often, and to solve them, it is enough to have a USB splitter (hub) on hand.
Separately, we note that the full-sized USB sockets in modern PCs and laptops have been replaced by more compact USB C (see below).
- USB C. Peripheral connector with a symmetrical contact group, which is often replaced by full-size USB ports on board modern PCs and laptops. Many new models of external sound cards are made for this interface. The exception to the rule are only individual instances for Thunderbolt (see below) - for them, it is Thunderbolt, and not USB C, that is indicated as a peripheral connection connector.
— Thunderbolt. A universal peripheral connector used primarily in Apple computers and laptops. It should be borne in mind that different generations of Thunderbolt differ in the type of physical connector: versions v1 and v2 use a miniDisplayPort socket, version v3 uses a USB C socket. So, when choosing a sound card with such a connection, you must definitely clarify this point. On the other hand, versions of Thunderbolt with different connectors are quite mutually compatible through the appropriate adapters.
— FireWire. It is also IEEE 1394. An interface for external devices, which some time ago enjoyed a certain popularity, but today it is practically obsolete.
- 3.5 mm (mini-jack). Mini-jack is one of the most common audio connectors. However, it is usually provided as one of the audio inputs (see below) and is rarely used as the main interface for connecting a sound card to an external device. Such a connection is found mainly in specialized gaming models, including those designed for use with consoles. At the same time, in such models, the mini-jack connector can be made combined, with the ability to connect both a linear (analog) signal via a conventional electrical wire, and an optical (digital) signal via a TOSLINK cable. Recall that the optical interface is notable for its complete insensitivity to external interference, it allows you to transmit multi-channel sound, however, cables for such a connection require care in handling.
— Bluetooth. Wireless connection according to the Bluetooth standard. It is found mainly in models designed for use with smartphones and tablets - there are few wired connectors in such gadgets, but Bluetooth modules are almost guaranteed. True, initially, with such a transmission, the sound is greatly compressed, which noticeably affects its quality; however, modern Bluetooth audio cards usually include support for aptX to remedy this shortcoming. Of course, the signal source must also support this technology - you should make sure of this before buying.Audiochip
Brand of the audio chip installed in the sound card.
The audio chip is one of the most important parts of a sound card, a kind of "heart" of the whole circuit, and it is on its characteristics that the sound quality and other capabilities of a particular model largely depend. Knowing the brand of the chip, you can easily find various information on it — official specifications, test results, reviews, etc. — and based on this, draw a conclusion to what extent this sound card is able to meet your requirements. Of course, for ordinary video cards (see "View") there is no need to delve into such details, but when choosing a gaming or audiophile model, they can be very useful.
Max. sampling rate
The highest sampling rate provided by the digital-to-analogue converter (DAC) of the audio card. For more details on the role of the DAC, see paragraph "Bit depth" above. Here we note that the quality of its work directly depends on the sampling frequency: the higher it is, the less distortion occurs when converting sound.
Usually in sound cards there are standard values for the maximum sampling rate:
44.1 kHz — corresponds to the sound quality of Audio CD;
48 kHz — DVD;
96 kHz — DVD-Audio 5.1;
192 kHz — DVD-Audio 2.0 (two-channel audio has a higher sampling rate than multi-channel audio for a number of reasons), the highest value in modern consumer-grade sound cards.
Another specific point is that the quality of sound played on a computer cannot be higher than the capabilities of a sound card. In other words, if an audio file is recorded at a higher sampling rate than the audio card can provide, its sound quality will be reduced: for example, on a 44.1 kHz card, even DVD-Audio sound will sound like an Audio CD. Therefore, if you want to fully enjoy high-quality sound, you should choose a model with a high sampling rate.
Signal-to-noise ratio
This parameter determines the ratio of the "clean" sound produced by the DAC at the output to all extraneous noise. As such, it is a pretty strong indicator of sound purity. According to the signal-to-noise ratio, DACs in modern sound cards can be divided as follows:
up to 90 dB — initial level;
90-100 dB — average level, advanced "home" models;
more than 100 dB — professional level.
Signal-to-noise ratio
The signal-to-noise ratio provided by the analogue-to-digital converter (ADC) of the sound card in the processed signal. For more information about this ratio, see the paragraph of the same name above. Here we note that in domestic use it does not play a decisive role, but if you plan to record sound in good quality, you should choose a card with a high value of this indicator.
mini-Jack (3.5 mm)
The number of inputs in the design of the sound card using 3.5 mm mini-Jack connectors. This connector, usually used to transmit an analogue signal, is one of the most popular in modern audio technology. Speaking of inputs, it's worth noting that most computer microphones are designed to plug into the 3.5mm jack; this also applies to separate microphone plugs on headsets. At the same time, the specific purpose of the mini-jack sockets in different sound cards may be different; Moreover, in some models, the same socket can be reconfigured and even change its purpose (from input to output and vice versa). These points, usually, are specified in the characteristics.
Using a simple adapter, you can also connect a 6.35 mm plug (Jack) to the 3.5 mm jack.
Optical S/P-DIF
The number of
S/P-DIF optical outputs provided in the design of the sound card.
S/P-DIF is a digital audio transmission standard, including multichannel, quite widespread in home acoustics. At the hardware level, this standard has two versions — coaxial (see below) and optical, which is discussed here. The TOSLINK fiber optic cable used for this type of connection is highly resistant to interference: electromagnetic pickups do not interact with the light pulses that transmit the signal. On the other hand, such a cable is more expensive than coaxial electrical wire and requires careful handling — strong pressure or a kink can damage the fiber.