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Comparison FiiO Q1 vs FiiO A3

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FiiO Q1
FiiO A3
FiiO Q1FiiO A3
from $93.69 up to $97.44
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from £166.51 
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Typeportableportable
DACBurr-Brown PCM5102
Specs
DAC sample rate96 kHz
DAC bit depth24 bit
Headphone impedance16 – 150 Ohm16 – 150 Ohm
Power (32 Ohm)190 mW270 mW
Power (16 ohm)450 mW
Frequency range20 – 20000 Hz20 – 20000 Hz
Signal to noise ratio107 dB108 dB
Coef. harmonic distortion0.005 %0.004 %
Functions and features
Gain Control
 /high and Low gain modes/
Bass control
 /Bass Boost/
 /Bass Boost/
Level adjustmentwheelwheel
Connectors
Inputs
mini-Jack (3.5 mm) /combined with Mini-Jack output (3.5 mm)/
USB (Type B)
mini-Jack (3.5 mm)
 
Outputs
mini-Jack (3.5 mm) /combined with Mini-Jack input (3.5 mm)/
 
Headphone outputs
1x mini-Jack (3.5 mm) шт
1x mini-Jack (3.5 mm) шт
Power source
Power type
battery powered /1400 mA/
USB powered
battery powered /1400 mAh/
USB powered
Battery life30 h16 h
General
Metal body
Dimensions56x97x13 mm91х56х13 mm
Weight100 g92 g
Added to E-Catalognovember 2015august 2015

DAC

DAC model — a digital-to-analogue converter installed in the amplifier.

In accordance with the name, the DAC is responsible for converting a digital signal (for example, coming to the optical input or USB, see "Inputs") into an analogue format, with which the amplifier directly works. The presence of such a converter in an external "amplifier" is important, given the fact that many popular signal sources — such as smartphones or built-in sound cards — are equipped with fairly simple and inexpensive DACs with low sound quality; on external equipment, this quality can be much higher. And the quality of the conversion and, accordingly, the characteristics of the output sound directly depend on the characteristics of the DAC: even the most advanced power amplifier will not “save” a signal converted with significant errors. Accordingly, knowing the converter model, you can find detailed data on it — from official specifications to practical reviews — and evaluate how an amplifier with such a module meets your requirements.

DAC sample rate

The sampling rate of the digital-to-analogue converter (DAC) installed in the amplifier. Recall that such a converter is responsible for converting digital audio into an analogue audio signal, which is then processed by the main amplifier and fed to the headphones (or other analogue audio device).

The sound in digital form is most often recorded as follows: the original sinusoid of the analogue audio signal is divided into separate sections (samples) — “steps” of a certain length and height, and each of these steps is encoded with its own set of numbers. The sampling rate determines how many such steps there are in a certain section of the original audio signal. Accordingly, the higher this frequency, the more accurately the digital record corresponds to the original signal; on the other hand, an increase in the number of samples per unit of time increases the volume of files and increases the requirements for the hardware power of digital circuits.

Specifically, for a DAC, the native sampling rate of such a module is, in fact, the maximum sampling rate of the incoming digital signal that the converter can effectively handle. With higher input values, the sound quality will at best be limited by the capabilities of the DAC, at worst, the amplifier will not be able to work correctly at all. Anyway, higher numbers in this paragraph (ceteris paribus) mean a more advanced and high-quality converter; on the other hand, this moment significantly affects the...cost, and you can evaluate all the capabilities of a high-end DAC only on audio materials of the appropriate quality.

As for specific numbers, the lowest value that can be found in headphone amplifiers is 44 kHz. According to the laws of physics, it is this sampling frequency that is the minimum necessary for the full transmission of all human-audible sound frequencies (16 — 22,000 Hz), and it is this frequency that is used in the Audio CD format. Many models provide values in 96 kHz and 192 kHz (this is already enough to work with different types of DVD-Audio), and in the most advanced devices this figure can reach 384 kHz and even 768 kHz.

DAC bit depth

The capacity of the digital-to-analogue converter (DAC) installed in the amplifier. Recall that such a converter is responsible for converting digital audio into an analogue audio signal, which is then processed by the main amplifier and fed to the headphones (or other analogue audio device).

The sound in digital form is most often recorded as follows: the original sinusoid of the analogue audio signal is divided into separate sections (samples) — “steps” of a certain length and height, and each of these steps is encoded with its own set of numbers. In this case, the "height" (level) of each step cannot be an arbitrary value — a specific value is selected from a specific list. The bit depth determines how many options this list contains: for example, an indicator of 16 bits means a list of 2 to the power of 16, that is, 2 ^ 16 \u003d 65536 level options. Accordingly, the higher the bit depth — the closer the level of each sample will be to the level of the corresponding section of the sinusoid, the smaller the deviation from the original signal in cases where the original level falls between fixed values. Thus, a high bit depth has a positive effect on the quality and reliability of the sound; on the other hand, it significantly affects the volume of audio materials and the requirements for processing power of the equipment for their processing.

Specifically, for a DAC, the native bit depth of such a module is, in fact, the maximum bit width of the inc...oming digital signal that the converter is able to effectively handle. With higher input values, the sound quality will at best be limited by the capabilities of the DAC, at worst, the device will not be able to work correctly at all. Anyway, higher numbers in this paragraph (ceteris paribus) mean a more advanced and high-quality converter; on the other hand, this moment significantly affects the cost, and you can evaluate all the capabilities of a high-end DAC only on audio materials of the appropriate quality.

As for specific values, the standard options in modern headphone amplifiers are 16 bits, 24 bits and 32 bits. The first value is used, in particular, for the Audio CD format, the second is found in the lossless APE and ALAC formats, and 32 bits may be required to work with FLAC and certain high-end standards.

Power (32 Ohm)

Rated power delivered by the amplifier when connected to headphones (or other load) with an impedance of 32 ohms.

By itself, the rated power is the highest average power that the device is capable of delivering for a long time without overloading; individual "jumps" of the signal may have a higher level, but in general, the capabilities of the amplifier are determined primarily by this indicator. At the same time, the physical features of the audio equipment are such that the actual power delivered to the load will depend on the resistance of this load. Therefore, in the characteristics of headphone amplifiers, data is often given for different impedance values. A resistance of 32 ohms allows you to achieve quite good sound quality by the standards of low-impedance headphones, while it is not so high as to create problems for the built-in amplifiers of smartphones and other compact equipment. Therefore, most wired general-purpose (non-professional) headphones are made precisely in this resistance, and if the amplifier characteristics generally indicate power for a certain impedance, then most often it is for 32 ohms.

In the most modest modern amplifiers, the output power at this impedance is between 10 and 250 mW ; values of 250 – 500 mW can be called average, 500 – 100 mW are above average, and the most powerful models are capable of delivering ...f="/list/788/pr-19429 /">more than 1000 watts. The choice for specific power indicators depends on the sensitivity of the headphones used, as well as on the sound pressure level (in other words, loudness), which is planned to be achieved by the amplifier. There are special formulas and tables that allow you to calculate the minimum required power for a certain volume at a given sensitivity of the "ears". However, in the case of 32-ohm headphones, it does not always make sense to "get into the calculations." For example, the mentioned 10 mW is more than enough to drive headphones with a modest sensitivity of 96 dB to a volume of more than 105 dB — this is already enough to listen to music at quite a decent volume. And in order to achieve the same "ears" level of 120 dB, which provides a full perception of the loudest sounds (like explosions, thunder, etc.), you need to give out a power slightly higher than 251 mW. So in fact, you have to pay attention to this characteristic and resort to calculations / tables mainly in those cases when you have to use 32 Ohm headphones with a relatively low sensitivity — 95 dB or less.

Power (16 ohm)

Rated power delivered by the amplifier when connected to headphones (or other load) with an impedance of 16 ohms.

By itself, the rated power is the highest average power that the device is capable of delivering for a long time without overloading; individual "jumps" of the signal may have a higher level, but in general, the capabilities of the amplifier are determined primarily by this indicator. At the same time, the physical features of the audio equipment are such that the actual power delivered to the load will depend on the resistance of this load. Therefore, in the characteristics of headphone amplifiers, data is often given for different impedance values. And 16 ohms is a rather low resistance indicator even for low-resistance "ears"; such characteristics are provided mainly in general-purpose headphones designed for pocket gadgets with low-power amplifiers.

As for the choice for specific power values, it depends on the sensitivity of the headphones used, as well as on the sound pressure level (in other words, loudness) that is planned to be achieved by the amplifier. There are special formulas and tables that allow you to calculate the minimum required power for a certain volume at a given sensitivity of the "ears". At the same time, it is worth noting that at 16 ohms, even the most low-power modern “amps” are capable of delivering about 20 mW — this is enough to drive headphones with a sensitivity of 88 dB (far from the highest figure) to a vo...lume of 105 dB (the minimum value recommended for a complete listening experience). And in most amplifiers, when operated with a given impedance, they provide much more power. So paying attention to this point and going into the calculations makes sense mainly either with low sensitivity of the "ears" (less than the mentioned 88 dB), or if you want to end up with a level above 105 dB.

Signal to noise ratio

The ratio between the overall level of the desired signal produced by the amplifier and the level of background noise resulting from the operation of electronic components.

It is impossible to completely avoid background noise, but it is possible to reduce it to the lowest possible level. The higher the signal-to-noise ratio, the clearer the sound produced by the device, the less noticeable its own interference from the amplifier. In the most modest amplifiers from this point of view, this indicator ranges from 70 to 95 dB — not an outstanding, but quite acceptable value even for Hi-Fi equipment. You can often find higher numbers — 95 – 100 dB, 100 – 110 dB and even more than 110 dB. This characteristic is of particular importance when the amplifier operates as a component of a multi-component audio system (for example, "vinyl player — phono stage — preamplifier — headphone amplifier." The fact is that in such systems the final noise of all components at the output is summed up, and for sound purity it is extremely it is desirable that these noises be minimal

Separately, it is worth emphasizing that a high signal-to-noise ratio in itself does not guarantee high sound quality in general.

Coef. harmonic distortion

The coefficient of harmonic distortion that occurs during the operation of the amplifier.

Any electronic circuits are inevitably subject to such distortions, and the quality and reliability of the sound at the output depends on their level. Accordingly, ideally, the harmonic coefficient should be as low as possible. So, as a general rule, a level of 0.09% and below (hundredths of a percent) is considered good, and a level of less than 0.01% (thousandths of a percent) is excellent. The exception is lamp devices: higher values \u200b\u200bare allowed in them (in tenths of a percent), however, this point in many cases is not a drawback, but a feature (for more details, see "Lamp").

It is also worth noting that a low harmonic coefficient is especially important when using the amplifier as part of multicomponent audio systems — for example, when listening to music from a vinyl player with an external phono stage. The fact is that in such systems the sum of distortions from all components affects the final sound — and it, again, should be as low as possible.

Inputs

Types of inputs provided in the design of the amplifier.

Modern headphone amplifiers can be equipped with audio inputs of both analogue ( mini-Jack 3.5 mm, Jack 6.35 mm, RCA, XLR) and digital formats (S / P-DIF with coaxial or optical connection), as well as USB OTG and USB type ports b. Here is a more detailed description of each of these inputs:

— Mini-Jack (3.5 mm). One of the most popular modern audio connectors. In this case, it is mainly used to connect to an analogue audio signal amplifier; this can be a line-level signal or sound from the headphone output from an external device (these nuances should be specified separately), while the connector itself most often has a classic three-pin format and is responsible for both stereo channels at once. Due to its small size, the mini-jack is very convenient for use in portable models (see "Type"). On the other hand, it is less noise-resistant than a 6.35 mm Jack of similar design, and has less extensive capabilities — in particular, it is almost never used for balanced connection. Therefore, in stationary models, this interface is much less common.
Separately, we note that other types of inputs can also be built into the 3.5 mm...type hardware port — for example, coaxial and/or optical (see below for details). However, the presence of a mini-jack is indicated only if this connector is capable of operating in a traditional analogue format.

— Jack (6.35 mm). An audio connector, in many ways similar to the mini-jack described above — in particular, it is also used mainly for connecting an analogue audio signal. The key difference is in the larger sizes. Because of this, Jack type inputs are used much less frequently, and mainly in stationary technology (see "Type"); but, on the other hand, a large diameter expands the possibilities of the connector. First, the connection is more reliable than 3.5mm jacks, with less chance of interference and accidental disconnection. Secondly, such inputs can even be used for balanced connection (although such a possibility is far from mandatory, moreover, XLR connectors are more often used for balanced connection; see below about them and about a similar connection format). Therefore, for high-quality stationary equipment, such inputs are considered more preferable than mini-jack.

— RCA. RCA is technically a type of connector that can be used for a variety of purposes. However, in this case, a very specific application is implied — in the format of a line input (for an analogue audio signal). In this format, one physical connector is responsible for one channel of sound, so this type of input usually consists of a pair of jacks — for the left and right channels. In general, linear RCA is practically not used in portable devices, but it is very popular in stationary audio equipment. It is somewhat inferior to more advanced standards (like XLR, see below) in terms of functionality and noise immunity, but this interface is often quite enough for both everyday and simple professional use.

— XLR. Initially, XLR is a connector of a characteristic round shape, with a set of contacts in the form of pins (and sockets for them) and an additional retainer on the outer ring. It can have a different number of contacts and be used in different formats. However, in headphone amplifiers, when talking about XLR inputs, they usually mean an interface for balanced connection of an analogue (line) audio signal. Such an interface usually consists of at least a pair of three-pin connectors — one for each stereo channel (a rarer option is one common six-pin connector, in fact a two-in-one version). As for the balanced connection, this is a special format that uses three wires per channel (instead of the standard two) and a special way to process the signal at the input. Due to this method, interference due to third-party interference in the connection cable is mutually canceled when it enters the amplifier; in fact, the cable itself plays the role of a noise filter. This allows you to work even with fairly long wires without compromising the purity of the sound. On the other hand, XLR connectors are quite large, and balanced format support affects the cost of the device. Therefore, in general, this interface is considered professional, it is installed in amplifiers of the appropriate level, mostly stationary (with rare exceptions).

— Coaxial S/P-DIF. A variation of the S/P-DIF interface that uses an electrical cable (as opposed to the optical cable described below). In general, the S / P-DIF format allows you to transmit several channels of sound through one connector at once, including working with multi-channel formats (although stereo is most often used in headphone amplifiers). And the electrical version of this interface is somewhat cheaper than the optical one and does not require special care when handling the cable. Its disadvantage is some susceptibility to electromagnetic interference, however, to compensate for this moment, the cable is usually made shielded.
Note that the S / P-DIF coaxial input most often uses an RCA jack as a hardware connector. However, this interface should not be confused with the analogue RCA described above: these are fundamentally different standards that are not compatible with each other. In addition, in some models (in particular, portable ones), this type of input can be physically combined with a 3.5 mm jack; in this case, one socket can work in different formats (depending on the selected settings), and a cable with a special connector (or an appropriate adapter) is required to use the coaxial interface.

— Optical S/P-DIF. A variation of the S/P-DIF interface that uses a TOSLINK fibre optic cable to transmit digital audio in stereo or multi-channel format (however, the latter is not typical for headphone amplifiers). The main advantage of such a connection over the coaxial one described above is complete insensitivity to electromagnetic interference. On the other hand, the optical cable is quite delicate, it does not tolerate strong pressure and bending.
It is worth saying that in some amplifiers — especially portable ones — the optical input can be built directly into the 3.5 mm jack, and to work with such an input, you need a cable with a plug of the appropriate design. The connector itself can work in different formats — depending on the settings and the connected cable.

— USB (OTG). Initially, USB OTG is a standard that allows you to connect various USB peripherals (such as flash drives) to portable gadgets like smartphones or tablets. However, in headphone amplifiers, this function has its own specifics, it should be specified separately in each case. So, most models with USB OTG are portable, and in them this input is used in the classic format — to receive a digital audio signal from microUSB, USB-C or another similar connector in a portable gadget (if the gadget initially provides such an opportunity). But in stationary amplifiers (see "Type"), the name "USB OTG" can denote an interface for connecting to a PC, if this interface does not use USB Type B, but another type of connector. These nuances should be clarified separately.

— USB (Type B). Interface for connecting the amplifier to the USB port of a computer and transmitting sound in digital form; in other words, a connector for using the amplifier as an external sound card. Formally, USB Type B is a strictly defined type of USB connector that has a characteristic square shape; it is this connector that is usually installed in stationary models. But in portable devices, this role can be played by ports of a different type — for example, microUSB; however, they are also referred to as USB Type B in such cases.

Anyway, the point of connecting an amplifier in the format of an external sound card is, first of all, that the built-in sound cards of modern computers usually have rather modest characteristics, and much better sound can be achieved on external equipment.

Outputs

Types of additional outputs provided in the design of the amplifier.

We emphasize that in this case we are talking about additional outputs — that is, connectors that are NOT intended for connecting headphones (although these outputs can use the same types of connectors). The presence, type and number of headphone jacks are indicated separately in the specifications (see below — "Mini-Jack outputs (3.5 mm)", "6.35 mm outputs (Jack)", "XLR outputs", "Headphone outputs"). Additional outputs are usually analogue audio interfaces ( mini-Jack 3.5 mm, Jack 6.35 mm, RCA, XLR) or digital format (S/P-DIF in coaxial or optical design). Here is a more detailed description of each of these interfaces:

— Mini-Jack 3.5 mm. Perhaps the most common analogue audio connector nowadays. Among other things, it is widely used as a linear audio output — in particular, for connecting computer speakers and portable acoustics. There are several varieties of mini-jack, but headphone amplifiers usually use a traditional three-pin jack for transmitting stereo sound through a single connector as an additional output. Anyway, the connector itself is small and convenient for use in compact technology; however, in terms of functionality, reliability and connection quality, it is infer...ior to its “big brother” Jack 6.35 mm. Therefore, the presence of additional 3.5 mm mini-jack outputs is typical mainly for portable amplifiers (see "Type"), as well as for individual stationary models designed for compactness.
Separately, we note that other types of inputs can also be built into the 3.5 mm type hardware jack — for example, coaxial and/or optical (see below). However, the presence of a mini-jack is indicated only if this connector is capable of operating in a traditional analogue format.

— Jack (6.35 mm). An analogue of the 3.5 mm mini-Jack described above, which is used mainly in stationary audio equipment — this is due to the large size of this connector (although there are also portable models with additional outputs of this format among headphone amplifiers). However, such dimensions provide a number of advantages: in particular, the connection is more reliable and noise-resistant. In addition, it is quite possible to implement even a balanced connection through a 6.35 mm Jack (for more details, see “XLR” below), although this functionality is relatively rare in headphone amplifiers — the standard format of operation is used much more often, with the transmission of both channels of stereo sound through one 6.35 output mm.

— RCA. RCA is technically a type of connector that can be used for a variety of purposes. However, in this case, a very specific application is implied — in the line-out format (for analogue audio). In this format, one physical connector is responsible for one channel of sound, so this type of output usually consists of a pair of connectors — for the left and right channels. As for use, linear RCA will be convenient primarily for connecting the amplifier to various stationary audio equipment, mainly entry-level and mid-level. This interface itself is not particularly noise-resistant, however, with the proper quality of the connecting wires, it is quite capable of providing more than decent sound quality — quite sufficient not only for everyday use, but also for relatively uncomplicated professional use.

— XLR. The XLR connector has several varieties, differing in the number of contacts; however, all of them have contacts in the form of characteristic pins ("pins") and a round rim, complemented by a separate latch for maximum connection reliability. And as an additional audio output in headphone amplifiers, a three-pin XLR version with balanced connection support is most often used. Such an interface outputs a line-level analogue signal on a "one channel per connector" basis; so an XLR output usually includes at least two hardware jacks, stereo left and right. As for the balanced connection, this is a special format that uses three wires per channel (instead of the standard two) and a special way to process the signal at the receiver input. Due to this, interference arising from third-party interference in the connection cable is mutually canceled when it arrives at the receiver; in fact, the cable itself plays the role of a noise filter. This allows you to work even with fairly long wires without compromising the purity of the sound. On the other hand, the XLR connectors themselves are quite large, and the support for a balanced format affects the cost of the device. Therefore, in general, this interface is considered professional, it is installed in amplifiers of the appropriate level, and only stationary ones — it makes no sense to use additional outputs of this type in portable models for a number of reasons.

— Coaxial S/P-DIF. A variation of the S/P-DIF interface that uses an electrical cable (as opposed to the optical cable described below). The common features of all varieties of S / P-DIF are, firstly, the digital signal format, and secondly, the ability to transmit stereo or multi-channel sound over a single connector. Specifically, the coaxial version uses a shielded electrical cable; it does not have one hundred percent protection against interference, but it is cheaper than fibre optic and does not require special delicacy in handling. As for the application, it makes sense to look for a device with an S / P-DIF output (of any format) if you plan to use it to switch a digital signal — for example, broadcasting sound from a smartphone's microUSB port to the coaxial input of an external audio receiver. Such use in the case of headphone amplifiers is quite exotic, so outputs of this type have not received much distribution.

— Optical S/P-DIF. A variation of the S/P-DIF interface that uses a TOSLINK fibre optic cable. See above for more on S/P-DIF in general and its use in headphone amplifiers. Also note here that an optical cable requires more careful handling than coaxial, but it is practically not subject to electromagnetic interference, since light pulses are responsible for signal transmission in this case.
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