{"id":13397,"date":"2026-06-23T22:26:47","date_gmt":"2026-06-23T19:26:47","guid":{"rendered":"https:\/\/gear.neuropunk.ru\/?p=13397"},"modified":"2026-06-23T23:11:59","modified_gmt":"2026-06-23T20:11:59","slug":"audio-signal-chain","status":"publish","type":"post","link":"https:\/\/gear.neuropunk.ru\/en\/audio-signal-chain\/","title":{"rendered":"The Audio Signal Chain: From Computer to Headphones"},"content":{"rendered":"<div class=\"wpb-content-wrapper\"><p>[vc_row][vc_column][vc_column_text css=&#8221;&#8221; woodmart_inline=&#8221;no&#8221; text_larger=&#8221;no&#8221;]<\/p>\n<p style=\"font-size: 1.1em; font-style: italic; color: #aaa; border-left: 3px solid #d4af37; padding-left: 18px; margin: 8px 0 26px;\">The chain &#8220;computer \u2014 audio interface \u2014 amplifier \u2014 headphones&#8221; is the basic signal chain of a home studio. The quality of the signal at the output and the convenience of everyday work depend on how it is assembled and how the levels are set.<\/p>\n<p>A large share of the mistakes in such a chain comes down to two things: connection order and volume setting. In both, the signal can lose quality in places where it could be avoided. The cause is usually not the hardware, but the fact that the chain was assembled and set up at random.<\/p>\n<p>The article breaks the chain down step by step: connection order, balanced and unbalanced lines, the influence of the mains, how the connector set depends on the device class, the amplifier&#8217;s operating modes and \u2014 as a separate large section \u2014 setting the volume at each stage of the chain.<\/p>\n<p>The principles apply to any setup. The specific examples are given on the devices of a mid-budget home-studio setup \u2014 the Antelope Zen Go audio interface, the Topping L30 II and L70 amplifiers, the ADAM T7V monitors. The feature set of devices in this class is broadly the same: somewhere a connector differs, somewhere a switch is named differently, but the logic does not change. Transferring the scheme to other equipment is addressed in every block of the article.<\/p>\n<div style=\"background: #1d1b18; border: 1px solid #322f2a; border-radius: 10px; padding: 20px 26px; margin: 24px 0 8px;\">\n<div style=\"font-family: Oswald,sans-serif; text-transform: uppercase; letter-spacing: .12em; font-size: 13px; color: #d4af37; font-weight: 600; margin-bottom: 12px;\">Contents<\/div>\n<ul style=\"list-style: none; margin: 0; padding: 0; line-height: 2;\">\n<li><a style=\"color: #d4af37; text-decoration: none;\" href=\"#trakt-poryadok\">&#x1f517;  <span style=\"text-decoration: underline; text-decoration-color: #7a5a2e; text-underline-offset: 3px;\">Connection order<\/span><\/a><\/li>\n<li><a style=\"color: #d4af37; text-decoration: none;\" href=\"#trakt-balans\">&#x2696;&#xfe0f;  <span style=\"text-decoration: underline; text-decoration-color: #7a5a2e; text-underline-offset: 3px;\">Balanced vs unbalanced connection<\/span><\/a><\/li>\n<li><a style=\"color: #d4af37; text-decoration: none;\" href=\"#trakt-pitanie\">&#x26a1;  <span style=\"text-decoration: underline; text-decoration-color: #7a5a2e; text-underline-offset: 3px;\">Interference and hum in the chain<\/span><\/a><\/li>\n<li><a style=\"color: #d4af37; text-decoration: none;\" href=\"#trakt-stek\">&#x1f50c;  <span style=\"text-decoration: underline; text-decoration-color: #7a5a2e; text-underline-offset: 3px;\">Connector set and device class<\/span><\/a><\/li>\n<li><a style=\"color: #d4af37; text-decoration: none;\" href=\"#trakt-pochemu-usilitel\">&#x1f3a7;  <span style=\"text-decoration: underline; text-decoration-color: #7a5a2e; text-underline-offset: 3px;\">Why a dedicated amplifier<\/span><\/a><\/li>\n<li><a style=\"color: #d4af37; text-decoration: none;\" href=\"#trakt-usilitel\">&#x1f39a;&#xfe0f;  <span style=\"text-decoration: underline; text-decoration-color: #7a5a2e; text-underline-offset: 3px;\">Amplifier<\/span><\/a><\/li>\n<li><a style=\"color: #d4af37; text-decoration: none;\" href=\"#trakt-gain\">&#x1f4ca;  <span style=\"text-decoration: underline; text-decoration-color: #7a5a2e; text-underline-offset: 3px;\">Gain setting<\/span><\/a><\/li>\n<li><a style=\"color: #d4af37; text-decoration: none;\" href=\"#trakt-gromkost\">&#x1f50a;  <span style=\"text-decoration: underline; text-decoration-color: #7a5a2e; text-underline-offset: 3px;\">Volume at each stage<\/span><\/a><\/li>\n<li><a style=\"color: #d4af37; text-decoration: none;\" href=\"#trakt-checklist\">&#x2705;  <span style=\"text-decoration: underline; text-decoration-color: #7a5a2e; text-underline-offset: 3px;\">Checklist<\/span><\/a><\/li>\n<\/ul>\n<\/div>\n<p>[\/vc_column_text][\/vc_column][\/vc_row][vc_row][vc_column][vc_column_text css=&#8221;&#8221; woodmart_inline=&#8221;no&#8221; text_larger=&#8221;no&#8221;]<\/p>\n<div style=\"height: 2px; width: 44px; background: #d4af37; border-radius: 2px; margin: 58px 0 0;\"><\/div>\n<h2 id=\"trakt-poryadok\" style=\"margin: 14px 0 16px; padding: 0; scroll-margin-top: 100px;\">&#x1f517; Connection order<\/h2>\n<p>The chain consists of four stages, and the signal passes through them in turn. At each stage the signal changes its state \u2014 this is the key point, because the state of the signal determines which connector it must be fed into.<\/p>\n<p><strong>Computer<\/strong> \u2014 the source. It sends the signal to the audio interface in digital form \u2014 a stream of numbers over a USB cable. A digital stream cannot be fed straight into an analog amplifier: the amplifier works with voltage, not numbers, so the stream first passes through a DAC (digital-to-analog converter). The computer also has its own analog output \u2014 the built-in sound card, from which a signal can be fed into the amplifier, but that is a bad idea. Why \u2014 explained below.<\/p>\n<p><strong>Audio interface<\/strong> (sound card) \u2014 the translator. This is your DAC, which turns the stream of numbers into an analog electrical signal. At the output of the audio interface the signal is already analog, but weak \u2014 this is line level, the standard working level for passing a signal between pieces of equipment.<\/p>\n<p><strong>Amplifier<\/strong> \u2014 the power stage, the muscle of the chain. A line-level signal is not enough to properly drive headphones. The amplifier draws current from its own power supply and, thanks to its low output impedance, firmly controls the diaphragm \u2014 hence the crisp attacks and tight bass. What matters is not only its output power, but also its low output impedance, current headroom on peaks and a quiet noise floor (covered in detail in the section on the amplifier).<\/p>\n<p><strong>Headphones<\/strong> \u2014 the end of the chain, the load. Here the electrical signal turns into diaphragm motion \u2014 into sound.<\/p>\n<p><img decoding=\"async\" class=\"np-zoom\" style=\"display: block; width: 100%; height: auto; border-radius: 10px; margin: 30px 0 8px;\" src=\"https:\/\/gear.neuropunk.ru\/wp-content\/uploads\/diagrams\/scheme.jpg\" alt=\"Signal-chain diagram: computer \u2014 audio interface (DAC) \u2014 headphone amplifier \u2014 planar-magnetic headphones, plus studio monitors and power from a UPS\" \/><\/p>\n<p style=\"text-align: center; font-size: 0.9em; color: #aaa; margin: 10px 0 0; font-style: italic;\">The whole chain: colored lines \u2014 the signal and its state along each section, dashed \u2014 power from the UPS <span style=\"color: #8d8980;\">\u2014 &#x1f50d; click to enlarge<\/span><\/p>\n<h4>Why not &#8220;straight into the computer&#8221;<\/h4>\n<p>Every computer has its own audio output \u2014 a mini-jack into which headphones physically plug in. It is handled by an audio codec: a chip on the motherboard (on desktop PCs \u2014 usually from the Realtek family). The codec combines a DAC and a small headphone amplifier stage \u2014 both required blocks are there, and planar-magnetic headphones will play from the computer \u2014 but with insufficient headroom in level, noise and output current. The reason lies in the conditions under which this codec works.<\/p>\n<p>The codec is soldered inside the PC case, right next to the processor, graphics card and power circuits. This is an electrically noisy neighborhood, and the codec picks up interference from it \u2014 hence the familiar hum or whine that changes with graphics-card load. The output impedance of the built-in output is usually high and not stated in the specifications: Realtek reference designs assume around 75 \u03a9, although it varies noticeably across different codecs and board revisions. For a low-impedance load like the Neuropunk M1 this is bad: a high output impedance forms a voltage divider with the headphones. On the 16 \u03a9 M1, a source with 75 \u03a9 delivers only a small fraction of the signal into the load \u2014 the available level (SPL) and current drop sharply, and the electrical matching gets worse (covered in detail in the section on the amplifier). The codec shares its power with the digital part of the board.<\/p>\n<p>The audio interface moves the DAC and the analog section out of this noisy environment into a separate enclosure \u2014 with power decoupled from the digital circuits (from the USB bus or from its own adapter), and with a proper line output to the amplifier. The signal itself leaves the computer over USB in digital form, and a digital stream is almost immune to interference along the way. That is why this conversion is moved to where it is quiet.<\/p>\n<h3>Physical connection order<\/h3>\n<p>Connecting and first power-up are done in a particular sequence. It protects both the equipment and your hearing.<\/p>\n<div style=\"background: rgba(212,175,55,0.06); border: 1px solid #333; border-radius: 8px; padding: 16px 30px; margin: 22px 0;\">\n<ol style=\"margin: 0; padding-left: 18px; line-height: 1.7;\">\n<li style=\"margin: 8px 0;\">All devices are powered off, power cables unplugged from the outlet.<\/li>\n<li style=\"margin: 8px 0;\">The signal cables are assembled: computer \u2192 audio interface (USB), audio interface (line output) \u2192 amplifier (line input), amplifier \u2192 headphones.<\/li>\n<li style=\"margin: 8px 0;\">Device power is connected.<\/li>\n<li style=\"margin: 8px 0;\">Power-up goes from source to sink: first the computer and the audio interface, the amplifier last. The amplifier&#8217;s volume is turned all the way down before switching on.<\/li>\n<li style=\"margin: 8px 0;\">Power-down is in reverse order: the amplifier is switched off first.<\/li>\n<\/ol>\n<\/div>\n<p>The logic is that, when power is applied to or removed from a device, a short pulse \u2014 a click \u2014 can travel down the chain. The amplifier is switched on last and off first: if it is already powered off at the moment of the click, the pulse will not reach either the headphones or the monitors.<\/p>\n<h4>Transferring this to your own setup<\/h4>\n<p>There are four stages in this chain, and the order is the same. Only the connectors between the stages change \u2014 which cable exactly connects the audio interface to the amplifier depends on their models. A separate section below is devoted to this.<\/p>\n<p>[\/vc_column_text][\/vc_column][\/vc_row][vc_row][vc_column][vc_column_text css=&#8221;&#8221; woodmart_inline=&#8221;no&#8221; text_larger=&#8221;no&#8221;]<\/p>\n<div style=\"height: 2px; width: 44px; background: #d4af37; border-radius: 2px; margin: 58px 0 0;\"><\/div>\n<h2 id=\"trakt-balans\" style=\"margin: 14px 0 16px; padding: 0; scroll-margin-top: 100px;\">&#x2696;&#xfe0f; Balanced vs unbalanced connection<\/h2>\n<p>Between the audio interface and the amplifier the signal travels along a cable \u2014 a separate line for each channel (left, right) \u2014 and along the way the cable acts as an antenna, picking up interference from the surrounding equipment: the computer&#8217;s switching power supply, the graphics card, the monitor, the wiring in the wall. A signal can be carried over a cable in two ways, and they differ in how resistant they are to this interference.<\/p>\n<p><strong>Unbalanced<\/strong> \u2014 two conductors: signal and ground. The most common connector is RCA, the &#8220;cinch&#8221; plug. Interference picked up on the signal conductor adds to the signal, and the receiver gets them together. It can no longer separate them back out.<\/p>\n<p><strong>Balanced<\/strong> \u2014 three conductors: &#8220;hot,&#8221; &#8220;cold&#8221; and ground. In classic active balancing, the hot and cold carry the same signal, but on the cold it is inverted \u2014 a mirror copy of the hot. (There are also impedance-balanced outputs, where the cold does not carry a full copy of the signal; the line still rejects interference \u2014 because what matters is not signal symmetry but the equal impedance of the legs relative to ground.) The connectors are XLR and TRS (a jack with two rings on the plug).<\/p>\n<h4>How balancing removes interference<\/h4>\n<p>Both wires of a balanced line lie close together, so interference is induced on them equally \u2014 it is one and the same pickup on the hot and on the cold. The signal on the wires, however, is mirrored.<\/p>\n<p>At the input the receiver inverts the cold wire back and sums it with the hot. At this moment the following happens to the signal: the hot and the inverted cold are in phase, and when summed the signal doubles. With the interference it is the opposite: it was identical on both wires, but inverting the cold makes it opposite there, and when summed it is cancelled. The cancellation is not perfect: its depth is set by the CMRR parameter, and it is finite \u2014 it depends on the circuit, the cable and the accuracy of impedance matching. In a healthy system this is tens of decibels, which is enough to push the pickup below the level of the signal.<\/p>\n<p>Formally this is <strong>common-mode rejection<\/strong> (CMRR): whatever lands on both wires equally is subtracted at the input \u2014 the more completely, the more precisely the impedances of the legs are matched.<\/p>\n<div class=\"np-zoom\" style=\"background:#1d1b18;border:1px solid #322f2a;border-radius:10px;padding:14px;margin:30px 0 8px;\"><svg viewBox=\"0 0 680 322\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" style=\"display:block;width:100%;height:auto;\" role=\"img\" aria-label=\"Unbalanced and balanced connection: how balancing cancels interference\"><defs><marker id=\"mb\" viewBox=\"0 0 10 10\" refX=\"6\" refY=\"5\" markerWidth=\"6\" markerHeight=\"6\" orient=\"auto-start-reverse\"><path d=\"M2 1L8 5L2 9\" fill=\"none\" stroke=\"context-stroke\" stroke-width=\"1.6\" stroke-linecap=\"round\" stroke-linejoin=\"round\"\/><\/marker><\/defs><text x=\"36\" y=\"34\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"15\" fill=\"#d4af37\">Unbalanced \u2014 2 wires (1 channel)<\/text><line x1=\"350\" y1=\"46\" x2=\"350\" y2=\"82\" stroke=\"#f44336\" stroke-width=\"2.4\" stroke-dasharray=\"4 3\" marker-end=\"url(#mb)\"\/><text x=\"360\" y=\"52\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"12\" fill=\"#f44336\">interference<\/text><rect x=\"36\" y=\"64\" width=\"116\" height=\"50\" rx=\"8\" fill=\"#252320\" stroke=\"#4a463f\"\/><text x=\"94\" y=\"94\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"14\" fill=\"#e8e4d9\">Source<\/text><rect x=\"528\" y=\"64\" width=\"116\" height=\"50\" rx=\"8\" fill=\"#252320\" stroke=\"#4a463f\"\/><text x=\"586\" y=\"94\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"14\" fill=\"#e8e4d9\">Receiver<\/text><line x1=\"152\" y1=\"82\" x2=\"528\" y2=\"82\" stroke=\"#d4af37\" stroke-width=\"3\"\/><text x=\"205\" y=\"76\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#d4af37\">signal<\/text><line x1=\"152\" y1=\"104\" x2=\"528\" y2=\"104\" stroke=\"#6f6a61\" stroke-width=\"2\"\/><text x=\"205\" y=\"118\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#8d8980\">ground<\/text><text x=\"586\" y=\"138\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"12\" fill=\"#f44336\">signal + interference<\/text><text x=\"36\" y=\"190\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"15\" fill=\"#d4af37\">Balanced \u2014 3 wires (1 channel)<\/text><rect x=\"36\" y=\"208\" width=\"116\" height=\"84\" rx=\"8\" fill=\"#252320\" stroke=\"#4a463f\"\/><text x=\"94\" y=\"254\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"14\" fill=\"#e8e4d9\">Source<\/text><rect x=\"528\" y=\"208\" width=\"116\" height=\"84\" rx=\"8\" fill=\"#252320\" stroke=\"#4a463f\"\/><text x=\"586\" y=\"246\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"14\" fill=\"#e8e4d9\">Receiver<\/text><text x=\"586\" y=\"264\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"11\" fill=\"#a39d91\">subtracts<\/text><line x1=\"152\" y1=\"224\" x2=\"528\" y2=\"224\" stroke=\"#d4af37\" stroke-width=\"3\"\/><text x=\"200\" y=\"218\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#d4af37\">+ hot<\/text><line x1=\"152\" y1=\"250\" x2=\"528\" y2=\"250\" stroke=\"#d4af37\" stroke-width=\"3\" stroke-dasharray=\"7 4\"\/><text x=\"200\" y=\"244\" font-family=\"Oswald,sans-serif\" font-size=\"11\" fill=\"#d4af37\">\u2212 cold (mirrored)<\/text><line x1=\"152\" y1=\"276\" x2=\"528\" y2=\"276\" stroke=\"#6f6a61\" stroke-width=\"2\"\/><text x=\"470\" y=\"290\" font-family=\"Oswald,sans-serif\" font-size=\"11\" fill=\"#8d8980\">ground<\/text><line x1=\"345\" y1=\"192\" x2=\"345\" y2=\"224\" stroke=\"#f44336\" stroke-width=\"2.4\" stroke-dasharray=\"4 3\" marker-end=\"url(#mb)\"\/><line x1=\"378\" y1=\"192\" x2=\"378\" y2=\"250\" stroke=\"#f44336\" stroke-width=\"2.4\" stroke-dasharray=\"4 3\" marker-end=\"url(#mb)\"\/><text x=\"340\" y=\"186\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"12\" fill=\"#f44336\">interference \u2014 same on both<\/text><text x=\"586\" y=\"308\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"12\" fill=\"#3fae84\">interference cancels, signal \u00d72<\/text><\/svg><\/div>\n<p style=\"text-align: center; font-size: 0.9em; color: #aaa; margin: 10px 0 0; font-style: italic;\">Unbalanced adds the interference to the signal; balanced catches it equally on both wires and cancels it when subtracting <span style=\"color: #8d8980;\">\u2014 &#x1f50d; click to enlarge<\/span><\/p>\n<h4>Where this is needed in the chain<\/h4>\n<p>A balanced connection is justified on any line between devices, especially a long one or one running near sources of interference: &#8220;audio interface \u2192 amplifier,&#8221; &#8220;amplifier \u2192 monitors.&#8221; An unbalanced RCA line is simpler, but defenseless against pickup. Even a very short desktop run does not automatically make it safe \u2014 an unbalanced cable can pick up hum even over tens of centimeters of length, for example from the graphics card or the PC power supply. A balanced line is protected from such pickup by its very construction.<\/p>\n<h4>What it costs<\/h4>\n<p>A balanced connection is not just the cable. The balanced cable itself is cheap. What is expensive is the balanced wiring of the whole chain: both the output of one device and the input of the other must be balanced, and inside each there are paired symmetric stages. Every balanced connector on every device adds noticeably to its price. That is why at the budget level there is usually no balancing at all, and it appears as the class of the devices grows.<\/p>\n<p>If there is no balanced chain and the mains is noisy \u2014 part of the pickup is removed not by balancing, but by proper power and routing. That is the subject of the next section.<\/p>\n<p>[\/vc_column_text][\/vc_column][\/vc_row][vc_row][vc_column][vc_column_text css=&#8221;&#8221; woodmart_inline=&#8221;no&#8221; text_larger=&#8221;no&#8221;]<\/p>\n<div style=\"height: 2px; width: 44px; background: #d4af37; border-radius: 2px; margin: 58px 0 0;\"><\/div>\n<h2 id=\"trakt-pitanie\" style=\"margin: 14px 0 16px; padding: 0; scroll-margin-top: 100px;\">&#x26a1; Interference and hum in the chain<\/h2>\n<p>Hum and interference in the chain come in three types \u2014 each with its own cause, its own character and its own cure:<\/p>\n<div style=\"overflow-x: auto; -webkit-overflow-scrolling: touch; margin: 22px 0;\">\n<table style=\"width: 100%; min-width: 540px; border-collapse: collapse; margin: 0;\">\n<thead>\n<tr style=\"background: rgba(212,175,55,0.2);\">\n<th style=\"padding: 12px; border: 1px solid #333; text-align: left;\">Type<\/th>\n<th style=\"padding: 12px; border: 1px solid #333; text-align: left;\">How it sounds<\/th>\n<th style=\"padding: 12px; border: 1px solid #333; text-align: left;\">How it is cured<\/th>\n<\/tr>\n<\/thead>\n<tbody>\n<tr>\n<td style=\"padding: 12px; border: 1px solid #333;\"><strong>1. Mains interference<\/strong><\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">HF noise and crackle from the mains, depends on nearby appliances<\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">power conditioner, UPS<\/td>\n<\/tr>\n<tr>\n<td style=\"padding: 12px; border: 1px solid #333;\"><strong>2. Ground loop<\/strong><\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">steady 50 Hz hum and harmonics (100, 150)<\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">single power source, GND\/LIFT, isolator<\/td>\n<\/tr>\n<tr>\n<td style=\"padding: 12px; border: 1px solid #333;\"><strong>3. Digital hash from the PC<\/strong><\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">high &#8220;modem-like&#8221; whine, drifts with graphics-card load<\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">USB isolation, balanced line<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/div>\n<h3>Type 1 \u2014 interference from the mains<\/h3>\n<p>The outlet supplies the devices with power, but along with the power comes electrical garbage down the wires. Part of the hum in the chain originates here.<\/p>\n<div style=\"background: rgba(33,150,243,0.08); padding: 20px; border-radius: 8px; border-left: 4px solid #2196f3; margin: 24px 0;\">\n<h4 style=\"margin-top: 0; color: #2196f3;\">&#x1f6b0; An analogy \u2014 tap water<\/h4>\n<p style=\"margin-bottom: 0;\">Water flows from the tap, but in an old building rust and sand come along with it. You can drink it, but it is risky. Better to install a filter that keeps the sediment to itself. A power conditioner does the same thing with electricity.<\/p>\n<\/div>\n<p>The 230 V 50 Hz mains is never perfectly clean. On top of the sine wave sit high-frequency disturbances from the switching power supplies of nearby appliances \u2014 chargers, LED lamps, the fridge. Voltage sags and surges happen.<\/p>\n<p>A reasonable question: the audio interface is connected to the computer over USB \u2014 that is digital, and the pickup usually does not turn into the digital data itself. So where does the mains garbage in the DAC come from? The point is that USB carries not only data, but also power with a common ground \u2014 and it is through these that the noise reaches the analog section. The DAC and the analog part of the audio interface run not on USB data, but on a DC voltage, and that voltage is of mains origin: either from the audio interface&#8217;s own adapter in the outlet, or, if the audio interface is bus-powered, from the 5 V that the computer takes from its own power supply, which in turn takes it from the same outlet. Ripple and high-frequency garbage on this power get mixed into the analog signal at the DAC output \u2014 the block most sensitive to power cleanliness. That is how the mains reaches the sound, bypassing the digital USB.<\/p>\n<p>A <strong>power conditioner<\/strong> removes high-frequency garbage from the power: the cleaner the power, the lower the noise at the analog output of the audio interface. A <strong>UPS<\/strong> (uninterruptible power supply) does more \u2014 it keeps the devices running through sags and brief outages, and depending on its topology also stabilizes and filters the voltage (the difference between the types is below).<\/p>\n<h4>&#x1f50b; The UPS \u2014 a backup supply for the studio<\/h4>\n<p>A power conditioner fights mains interference, but there is a separate class of problems it does not cover: sudden loss of the mains, prolonged voltage sags and surges. For a studio this is no longer about &#8220;hum,&#8221; but about protecting your work and your gear. An uninterruptible power supply (UPS) addresses exactly this.<\/p>\n<p>What it gives you:<\/p>\n<ul>\n<li><strong>It saves the project.<\/strong> When the power goes out, the computer shuts down instantly and hard. An unsaved DAW session is lost, and the file system or the project itself can be corrupted. A UPS gives you a few minutes to calmly save and shut down properly.<\/li>\n<li><strong>It protects the gear.<\/strong> Voltage sags force the power supplies of the audio interface, DAC and amplifier to work at their limit; surges and pulses can destroy them. A UPS with the AVR function (automatic voltage regulation) pulls the mains back toward normal before it reaches the equipment.<\/li>\n<li><strong>It removes the emergency click.<\/strong> A sudden loss of power drives the same pulse down the chain as an incorrect power-up sequence. A UPS does not let the mains &#8220;break off&#8221; abruptly.<\/li>\n<\/ul>\n<h4>Which type to get<\/h4>\n<p>A UPS comes in three topologies, and the difference is fundamental:<\/p>\n<ul>\n<li><strong>Standby (off-line)<\/strong> \u2014 the cheapest, simply switches to the battery when the mains fails. The switchover is not instant, and it does not correct sags. A bit weak for a studio.<\/li>\n<li><strong>Line-interactive with AVR<\/strong> \u2014 continuously stabilizes the voltage without draining the battery, and only switches to the battery when the power goes out. The optimal balance of price and protection \u2014 the working choice for a desktop studio.<\/li>\n<li><strong>Online (double-conversion)<\/strong> \u2014 always powers the load through the inverter: zero switchover time and the cleanest possible output voltage. The best, but expensive, and often with its own fan noise \u2014 overkill for the home.<\/li>\n<\/ul>\n<div style=\"background: rgba(244,67,54,0.1); padding: 20px; border-radius: 8px; border-left: 4px solid #f44336; margin: 24px 0;\">\n<h4 style=\"margin-top: 0; color: #f44336;\">&#x26a0;&#xfe0f; Pure sine wave only<\/h4>\n<p style=\"margin-bottom: 0;\">On battery, cheap UPS units output not a sine wave but a stepped &#8220;staircase&#8221; (modified\/stepped sine). Power supplies with active PFC \u2014 and that includes computer PSUs and some audio gear \u2014 can behave unstably on such a waveform: hum, heat up more, rarely \u2014 even fail to start. There is no universal prohibition, but for studio gear a <strong>pure sine wave<\/strong> is preferable \u2014 it removes the compatibility question. In the specifications it is listed as &#8220;pure sine wave.&#8221;<\/p>\n<\/div>\n<h4>What rating to get<\/h4>\n<p>There is no need to chase long runtime \u2014 the job of a UPS is not &#8220;to play for an hour without power,&#8221; but to let you calmly save and ride out short outages. A rough load estimate: a PC with a monitor, the audio interface and the amplifier \u2014 that is usually 300\u2013400 W, plus active monitors (from 30 to 200 W per pair). With headroom, that is a UPS of 1000\u20131500 VA. If the monitors are powerful or the amplifier is class A \u2014 get one with headroom, not right at the limit.<\/p>\n<p>The job of a UPS is protection and continuity of power: so that the chain survives a surge, a sag and a power outage. As a bonus, when the whole chain is powered from a single UPS, all devices share a common ground point \u2014 this reduces the risk of a ground loop (more on it below).<\/p>\n<h3>Type 2 \u2014 the ground loop<\/h3>\n<p>A separate and the most common cause of hum is the ground loop. It arises when two devices in the chain are connected by two paths at once: the signal cable and the ground of the outlets. If the devices are plugged into different outlets, the ground potential of those outlets differs slightly, a current flows around the resulting loop, and a hum at 50 Hz and its harmonics \u2014 100, 150 Hz \u2014 appears in the headphones.<\/p>\n<div class=\"np-zoom\" style=\"background:#1d1b18;border:1px solid #322f2a;border-radius:10px;padding:14px;margin:30px 0 8px;\"><svg viewBox=\"0 0 680 256\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" style=\"display:block;width:100%;height:auto;\" role=\"img\" aria-label=\"Ground loop: a loop formed by the signal cable and the outlet grounds\"><rect x=\"130\" y=\"92\" width=\"420\" height=\"116\" rx=\"14\" fill=\"none\" stroke=\"#f44336\" stroke-width=\"2\" stroke-dasharray=\"6 5\"\/><polygon points=\"328,87 340,92 328,97\" fill=\"#f44336\"\/><polygon points=\"352,203 340,208 352,213\" fill=\"#f44336\"\/><rect x=\"64\" y=\"64\" width=\"150\" height=\"56\" rx=\"8\" fill=\"#252320\" stroke=\"#4a463f\"\/><text x=\"139\" y=\"97\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"13\" fill=\"#e8e4d9\">Audio interface<\/text><rect x=\"466\" y=\"64\" width=\"150\" height=\"56\" rx=\"8\" fill=\"#252320\" stroke=\"#4a463f\"\/><text x=\"541\" y=\"97\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"13\" fill=\"#e8e4d9\">Amplifier<\/text><line x1=\"214\" y1=\"92\" x2=\"466\" y2=\"92\" stroke=\"#d4af37\" stroke-width=\"3\"\/><text x=\"340\" y=\"84\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#d4af37\">signal cable<\/text><line x1=\"119\" y1=\"208\" x2=\"159\" y2=\"208\" stroke=\"#8d8980\" stroke-width=\"2\"\/><line x1=\"126\" y1=\"214\" x2=\"152\" y2=\"214\" stroke=\"#8d8980\" stroke-width=\"2\"\/><line x1=\"133\" y1=\"220\" x2=\"145\" y2=\"220\" stroke=\"#8d8980\" stroke-width=\"2\"\/><text x=\"139\" y=\"240\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"11\" fill=\"#8d8980\">outlet 1 ground<\/text><line x1=\"521\" y1=\"208\" x2=\"561\" y2=\"208\" stroke=\"#8d8980\" stroke-width=\"2\"\/><line x1=\"528\" y1=\"214\" x2=\"554\" y2=\"214\" stroke=\"#8d8980\" stroke-width=\"2\"\/><line x1=\"535\" y1=\"220\" x2=\"547\" y2=\"220\" stroke=\"#8d8980\" stroke-width=\"2\"\/><text x=\"541\" y=\"240\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"11\" fill=\"#8d8980\">outlet 2 ground<\/text><text x=\"340\" y=\"150\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"14\" fill=\"#f44336\">loop current<\/text><text x=\"340\" y=\"172\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"13\" fill=\"#f44336\">\u223f 50 Hz hum<\/text><text x=\"340\" y=\"200\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#f44336\">different ground potential \u2192 current<\/text><\/svg><\/div>\n<p style=\"text-align: center; font-size: 0.9em; color: #aaa; margin: 10px 0 0; font-style: italic;\">Ground loop: the signal cable and the different outlet grounds form a loop through which current flows \u2014 and that is the hum <span style=\"color: #8d8980;\">\u2014 &#x1f50d; click to enlarge<\/span><\/p>\n<p>The main ways to cure it:<\/p>\n<ul>\n<li><strong>Single power source.<\/strong> The whole chain is plugged into one power conditioner or UPS. Then all devices share a common ground point, and the loop, as a rule, has nowhere to close. This is the first thing to do.<\/li>\n<li><strong>Ground switch on the amplifier.<\/strong> The L70 has a GND\/LIFT switch: in the LIFT position it transfers the amplifier&#8217;s signal (&#8220;chassis&#8221;) ground point to the connected equipment and breaks the loop. This concerns the signal ground, not the protective contact in the plug \u2014 the mains earth is not touched.<\/li>\n<li><strong>Ground-loop isolator.<\/strong> An inexpensive adapter inserted into the signal cable: inside is an isolating transformer \u2014 the signal passes through it, while the direct ground connection is broken and the loop disappears. A ready-made solution when single power and a ground switch are unavailable.<\/li>\n<\/ul>\n<h4>When the apartment has no earth<\/h4>\n<p>A common case in residential housing \u2014 outlets with no working earth. Without earth the chassis of the gear have no common reference point, and pickup that has nowhere to drain to keeps showing up as hum. The right solution here is electrical: an electrician should earth the outlets.<\/p>\n<p>What you must not do is remove or disconnect the earth contact in the plug to &#8220;get rid of the hum.&#8221; It will remove the hum, but the earth is in the mains as a safety measure, and removing it creates a risk of electric shock in the event of a fault. Hum is cured by ground decoupling, not by disconnecting the earth.<\/p>\n<h3>Type 3 \u2014 digital hash from the computer<\/h3>\n<p>The third type of hum is a high &#8220;modem-like&#8221; or chattering whine that changes along with the graphics-card load, and sometimes with mouse movement too. This is not a ground-loop hum (that is low and steady) and not the acoustic whine of the graphics card&#8217;s chokes \u2014 it is electromagnetic pickup from the computer&#8217;s digital section that has gotten into the analog signal.<\/p>\n<p>Why it &#8220;drifts&#8221;: the source is the graphics card&#8217;s switching voltage regulators (VRM) and the digital supply current itself, which jumps along with load and computation. The frequency and spectrum of this garbage change with PC activity, so the ear hears not a steady tone but a shifting whine.<\/p>\n<p>How it gets into the sound: via the common ground \u2014 most often through the USB ground. A bus-powered audio interface shares the computer&#8217;s noisy ground, and high-frequency garbage gets mixed into the analog after the DAC. A rarer path is the shield of an unbalanced RCA cable.<\/p>\n<p>How to cure precisely this type (not to be confused with the loop):<\/p>\n<ul>\n<li><strong>USB isolator.<\/strong> Galvanic isolation over USB \u2014 the most targeted means; it often requires a separate clean 5 V power supply.<\/li>\n<li><strong>Balanced line<\/strong> audio interface\u2192amplifier, where available \u2014 breaks the common path along the signal.<\/li>\n<li><strong>Power the audio interface not from the USB bus,<\/strong> but from an external adapter; a different (rear) USB port; route the cable farther from the graphics card; ferrite rings on the cables.<\/li>\n<\/ul>\n<p>A single power source and the GND\/LIFT switch remove part of the ground-borne pickup, but the USB pickup specifically is only removed by USB isolation.<\/p>\n<h4>A minimum at no cost<\/h4>\n<p>Before any purchases: power the whole chain from a single extension strip \u2014 this usually gives a common ground and removes the loop; keep signal cables short; do not run them parallel to power cables; move external mains adapters away from signal cables \u2014 they radiate interference, and their position noticeably affects the hum level.<\/p>\n<p>[\/vc_column_text][\/vc_column][\/vc_row][vc_row][vc_column][vc_column_text css=&#8221;&#8221; woodmart_inline=&#8221;no&#8221; text_larger=&#8221;no&#8221;]<\/p>\n<div style=\"height: 2px; width: 44px; background: #d4af37; border-radius: 2px; margin: 58px 0 0;\"><\/div>\n<h2 id=\"trakt-stek\" style=\"margin: 14px 0 16px; padding: 0; scroll-margin-top: 100px;\">&#x1f50c; Connector set and device class<\/h2>\n<p>The set of connectors on a device \u2014 its &#8220;stack&#8221; \u2014 is directly tied to price. The more expensive the model, the more input and output options it has. This is a consequence of the circuitry: balanced stages, additional outputs and converters cost money and appear as the device class grows.<\/p>\n<div class=\"np-zoom\" style=\"background:#1d1b18;border:1px solid #322f2a;border-radius:10px;padding:14px;margin:30px 0 8px;\"><svg viewBox=\"0 0 680 250\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" style=\"display:block;width:100%;height:auto;\" role=\"img\" aria-label=\"Chain connectors: RCA, 3.5 mini-jack, 6.35 jack, XLR, 4-pin XLR, 4.4 mm, USB-C\"><circle cx=\"100\" cy=\"64\" r=\"17\" fill=\"#252320\" stroke=\"#8d8980\" stroke-width=\"2\"\/><circle cx=\"100\" cy=\"64\" r=\"4.5\" fill=\"#d4af37\"\/><text x=\"100\" y=\"110\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"12.5\" fill=\"#e8e4d9\">RCA &#8220;cinch&#8221;<\/text><text x=\"100\" y=\"126\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"10.5\" fill=\"#8d8980\">unbalanced<\/text><rect x=\"222\" y=\"55\" width=\"28\" height=\"18\" rx=\"3\" fill=\"#2b2a25\" stroke=\"#4a463f\" stroke-width=\"1.5\"\/><rect x=\"250\" y=\"57\" width=\"46\" height=\"14\" rx=\"7\" fill=\"#d4af37\"\/><rect x=\"272\" y=\"57\" width=\"3\" height=\"14\" fill=\"#1d1b18\"\/><rect x=\"282\" y=\"57\" width=\"3\" height=\"14\" fill=\"#1d1b18\"\/><text x=\"259\" y=\"110\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"12.5\" fill=\"#e8e4d9\">3.5 mm mini-jack<\/text><text x=\"259\" y=\"126\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"10.5\" fill=\"#8d8980\">unbalanced<\/text><rect x=\"364\" y=\"51\" width=\"44\" height=\"26\" rx=\"3\" fill=\"#2b2a25\" stroke=\"#4a463f\" stroke-width=\"1.5\"\/><rect x=\"408\" y=\"53\" width=\"69\" height=\"22\" rx=\"11\" fill=\"#d4af37\"\/><rect x=\"445\" y=\"53\" width=\"3.5\" height=\"22\" fill=\"#1d1b18\"\/><rect x=\"457\" y=\"53\" width=\"3.5\" height=\"22\" fill=\"#1d1b18\"\/><text x=\"420\" y=\"110\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"12.5\" fill=\"#e8e4d9\">6.35 mm jack (TRS)<\/text><text x=\"420\" y=\"126\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"10.5\" fill=\"#8d8980\">balanced \/ unbalanced<\/text><rect x=\"572\" y=\"40\" width=\"16\" height=\"7\" rx=\"2\" fill=\"#252320\" stroke=\"#8d8980\" stroke-width=\"1.5\"\/><circle cx=\"580\" cy=\"64\" r=\"22\" fill=\"#252320\" stroke=\"#8d8980\" stroke-width=\"2\"\/><circle cx=\"580\" cy=\"64\" r=\"17\" fill=\"#1d1b18\"\/><circle cx=\"580\" cy=\"55\" r=\"3.4\" fill=\"#d4af37\"\/><circle cx=\"571\" cy=\"70\" r=\"3.4\" fill=\"#d4af37\"\/><circle cx=\"589\" cy=\"70\" r=\"3.4\" fill=\"#d4af37\"\/><text x=\"580\" y=\"110\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"12.5\" fill=\"#e8e4d9\">XLR<\/text><text x=\"580\" y=\"126\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"10.5\" fill=\"#8d8980\">balanced<\/text><rect x=\"172\" y=\"138\" width=\"16\" height=\"7\" rx=\"2\" fill=\"#252320\" stroke=\"#8d8980\" stroke-width=\"1.5\"\/><circle cx=\"180\" cy=\"162\" r=\"22\" fill=\"#252320\" stroke=\"#8d8980\" stroke-width=\"2\"\/><circle cx=\"180\" cy=\"162\" r=\"17\" fill=\"#1d1b18\"\/><circle cx=\"172\" cy=\"156\" r=\"3.4\" fill=\"#d4af37\"\/><circle cx=\"188\" cy=\"156\" r=\"3.4\" fill=\"#d4af37\"\/><circle cx=\"176\" cy=\"170\" r=\"3.4\" fill=\"#d4af37\"\/><circle cx=\"184\" cy=\"170\" r=\"3.4\" fill=\"#d4af37\"\/><text x=\"180\" y=\"208\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"12.5\" fill=\"#e8e4d9\">4-pin XLR<\/text><text x=\"180\" y=\"224\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"10.5\" fill=\"#8d8980\">balanced, headphones<\/text><rect x=\"290\" y=\"151\" width=\"44\" height=\"22\" rx=\"3\" fill=\"#2b2a25\" stroke=\"#4a463f\" stroke-width=\"1.5\"\/><rect x=\"334\" y=\"153\" width=\"56\" height=\"18\" rx=\"9\" fill=\"#d4af37\"\/><rect x=\"352\" y=\"153\" width=\"3\" height=\"18\" fill=\"#1d1b18\"\/><rect x=\"361\" y=\"153\" width=\"3\" height=\"18\" fill=\"#1d1b18\"\/><rect x=\"370\" y=\"153\" width=\"3\" height=\"18\" fill=\"#1d1b18\"\/><text x=\"340\" y=\"208\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"12.5\" fill=\"#e8e4d9\">4.4 mm Pentaconn<\/text><text x=\"340\" y=\"224\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"10.5\" fill=\"#8d8980\">balanced, headphones<\/text><rect x=\"478\" y=\"154\" width=\"44\" height=\"16\" rx=\"8\" fill=\"#2b2a25\" stroke=\"#8d8980\" stroke-width=\"2\"\/><rect x=\"486\" y=\"160\" width=\"28\" height=\"4\" rx=\"2\" fill=\"#565550\"\/><text x=\"500\" y=\"208\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"12.5\" fill=\"#e8e4d9\">USB-C<\/text><text x=\"500\" y=\"224\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"10.5\" fill=\"#8d8980\">digital signal<\/text><\/svg><\/div>\n<p style=\"text-align: center; font-size: 0.9em; color: #aaa; margin: 10px 0 0; font-style: italic;\">Chain connectors: which is balanced, which is unbalanced, which is digital <span style=\"color: #8d8980;\">\u2014 &#x1f50d; click to enlarge<\/span><\/p>\n<div style=\"overflow-x: auto; -webkit-overflow-scrolling: touch; margin: 22px 0;\">\n<table style=\"width: 100%; min-width: 540px; border-collapse: collapse; margin: 0;\">\n<thead>\n<tr style=\"background: rgba(212,175,55,0.2);\">\n<th style=\"padding: 12px; border: 1px solid #333; text-align: left;\">Class<\/th>\n<th style=\"padding: 12px; border: 1px solid #333; text-align: left;\">Audio interface<\/th>\n<th style=\"padding: 12px; border: 1px solid #333; text-align: left;\">Amplifier<\/th>\n<\/tr>\n<\/thead>\n<tbody>\n<tr>\n<td style=\"padding: 12px; border: 1px solid #333;\"><strong>Budget<\/strong><\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">USB, RCA or mini-jack output<\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">RCA input and output, 6.35 mm headphone output<\/td>\n<\/tr>\n<tr>\n<td style=\"padding: 12px; border: 1px solid #333;\"><strong>Mid<\/strong><\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">USB, balanced TRS outputs, a separate monitor output<\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">RCA and XLR inputs, 6.35 mm and balanced 4.4 mm headphone outputs<\/td>\n<\/tr>\n<tr>\n<td style=\"padding: 12px; border: 1px solid #333;\"><strong>High-end<\/strong><\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">USB, balanced XLR\/TRS inputs and outputs, several monitor buses<\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">Balanced XLR inputs, a full set of headphone outputs, including 4-pin XLR<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/div>\n<h4>Why this matters when buying<\/h4>\n<p>The connectors of two adjacent stages must match. A balanced line works only if both ends are balanced \u2014 both the output of the audio interface and the input of the amplifier. A balanced connector on just one end gives nothing: the line works as unbalanced. That is why you check the connector set before buying, not after: it determines which connections are even possible in the assembled chain.<\/p>\n<p>At the budget level there is usually no balancing \u2014 only RCA and mini-jack. For a desktop chain this is a workable option. But if long lines to monitors are planned or the chain is noisy, models with balanced connectors are worth considering right away.<\/p>\n<p>[\/vc_column_text][\/vc_column][\/vc_row][vc_row][vc_column][vc_column_text css=&#8221;&#8221; woodmart_inline=&#8221;no&#8221; text_larger=&#8221;no&#8221;]<\/p>\n<div style=\"height: 2px; width: 44px; background: #d4af37; border-radius: 2px; margin: 58px 0 0;\"><\/div>\n<h2 id=\"trakt-pochemu-usilitel\" style=\"margin: 14px 0 16px; padding: 0; scroll-margin-top: 100px;\">&#x1f3a7; Why a dedicated amplifier<\/h2>\n<p>The most common question: the computer and the sound card have a headphone output with a supposedly built-in amplifier \u2014 will it handle the M1? In the general case, no. First, there are no desktop sound cards on the market with a full-fledged amplifier. The current exception is the Topping E2x2, E4x4 line. But even there the amplifier is &#8220;mobile&#8221; \u2014 it is powered from the same USB and has no separate PSU plugged into the 230 V mains. Second, the main reason does not come down to volume and is not at all obvious.<\/p>\n<h4>&#8220;16 \u03a9&#8221; does not mean &#8220;an easy load&#8221;<\/h4>\n<p>The built-in output of a computer or sound card delivers a few to a few dozen milliwatts into the headphones. A counter-argument arises: the M1&#8217;s impedance is only 16 \u03a9, the load is low \u2014 so they must be easy to drive. In reality the dependence is the opposite. Loudness is determined not by impedance, but by the sensitivity of the headphones; a low impedance, meanwhile, demands more current from the source (I = U \/ R). The M1&#8217;s planar-magnetic diaphragm is large and light, and it is moved by current across its whole area. The combination &#8220;16 \u03a9 plus moderate sensitivity&#8221; is the least convenient load for a weak output: it demands both voltage and current at once.<\/p>\n<div style=\"display: flex; gap: 18px; justify-content: center; flex-wrap: wrap; margin: 20px 0 6px;\"><span style=\"font-family: monospace; background: #252320; border: 1px solid #4a463f; border-radius: 6px; padding: 10px 22px; color: #d4af37; font-size: 17px; letter-spacing: 1px;\">I = U \/ R<\/span><span style=\"font-family: monospace; background: #252320; border: 1px solid #4a463f; border-radius: 6px; padding: 10px 22px; color: #d4af37; font-size: 17px; letter-spacing: 1px;\">P = U\u00b2 \/ R<\/span><\/div>\n<p style=\"text-align: center; font-size: 0.85em; color: #8d8980; margin: 0 0 6px;\">loudness, voltage, current and power are linked \u2014 at moderate volume this is milliwatts, but on peaks you need headroom<\/p>\n<h4>What determines the result<\/h4>\n<ul>\n<li><strong>Low output impedance.<\/strong> On a 16 \u03a9 load the output acts as a voltage divider: the higher its impedance, the less signal reaches the headphones. At 1 \u03a9 the loss is about \u22120.5 dB, at 20 \u03a9 it is already \u22127 dB, at 75 \u03a9 \u2014 \u221215 dB; with a high-impedance output you lose both loudness and peak headroom. A low impedance additionally helps to damp the diaphragm&#8217;s back-EMF \u2014 attacks are crisper, bass tighter; on planars with a flat impedance curve this effect is weaker than on dynamic headphones, but the level loss remains in any case.<\/li>\n<li><strong>Current and power headroom on peaks.<\/strong> A musical signal consists of bursts (transients), and a peak demands instantaneous current. For low-sensitivity planars, peaks of 110\u2013115 dB are no longer milliwatts but on the order of a hundred or two mW into 16 \u03a9. A weak output sags or starts to distort at such a peak; a dedicated amplifier (or an interface with power headroom) delivers this current with margin.<\/li>\n<li><strong>A quiet noise floor.<\/strong> What matters is not the &#8220;loud&#8221; SNR in dB from the marketing, but the absolute noise level relative to the headphones&#8217; sensitivity.<\/li>\n<\/ul>\n<p>Hence the role of the rated power. In the specifications an amplifier shows a few watts (for example, 3.5 W into 16 \u03a9), an interface output \u2014 hundreds of milliwatts, but this figure by itself says little: the stated maximum is reached at the limit, and without specifying the load it is meaningless. What decides is not it, but the output&#8217;s ability to deliver current on a peak at a low impedance. That is why comparing outputs by a single watt figure is incorrect \u2014 but treating power as insignificant is wrong too: on a 16 \u03a9 low-sensitivity load there must be enough of it precisely on the transients.<\/p>\n<h4>Output impedance: typical values<\/h4>\n<p>The spread is large. The built-in sound card \u2014 around 75 \u03a9, typical interfaces (Antelope Zen Go, Audient iD4) \u2014 about 20\u201327 \u03a9, a dedicated amplifier \u2014 fractions of an ohm (the Topping L70 around 0.1 \u03a9). On a 16 \u03a9 load this translates directly into level loss: from an interface at 20\u201327 \u03a9 about 7 dB less reaches the M1, from the onboard output at 75 \u03a9 \u2014 15 dB, whereas from an amplifier \u2014 a fraction of a decibel. The exception among interfaces is the Topping E2x2\/E4x4: they are built on an &#8220;amplifier&#8221; topology and give about 1 \u03a9, that is, their output is almost like that of a dedicated amplifier, but even there it has its own nuances.<\/p>\n<div class=\"np-zoom\" style=\"background:#1d1b18;border:1px solid #322f2a;border-radius:10px;padding:14px;margin:30px 0 8px;\"><svg viewBox=\"0 0 760 284\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" style=\"display:block;width:100%;height:auto;\" role=\"img\" aria-label=\"Comparison of headphone outputs for the M1 (16 \u03a9). 16 \u03a9 is the impedance of the headphones themselves \u2014 the load. The sources have different output impedance Zout and maximum power: the dedicated L70 amplifier \u2014 Zout 0.1 \u03a9 and 3.5 W; Topping E2x2\/E4x4 \u2014 1 \u03a9 and 580 mW; a typical interface \u2014 20\u201327 \u03a9 and about 100 mW; PC onboard output \u2014 75 \u03a9 and about 30 mW\"><text x=\"36\" y=\"24\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"15\" fill=\"#d4af37\">Comparison of headphone outputs for the M1 (16 \u03a9)<\/text><text x=\"36\" y=\"46\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#8d8980\">16 \u03a9 is the headphones themselves (the load); outputs differ in Zout and power<\/text><text x=\"36\" y=\"72\" font-family=\"Oswald,sans-serif\" font-size=\"11.5\" fill=\"#8d8980\">output impedance Zout \u2014 lower is better<\/text><text x=\"724\" y=\"72\" font-family=\"Oswald,sans-serif\" font-size=\"11.5\" fill=\"#8d8980\" text-anchor=\"end\">power into 16 \u03a9 \u2014 higher is better<\/text><text x=\"36\" y=\"100\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#e8e4d9\">Dedicated amplifier (L70)<\/text><rect x=\"36\" y=\"106\" width=\"4\" height=\"18\" rx=\"2\" fill=\"#3fae84\"\/><text x=\"48\" y=\"120\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#a39d91\">\u2248 0.1 \u03a9<\/text><rect x=\"364\" y=\"106\" width=\"360\" height=\"18\" rx=\"2\" fill=\"#3fae84\"\/><text x=\"356\" y=\"120\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#a39d91\" text-anchor=\"end\">\u2248 3.5 W<\/text><text x=\"36\" y=\"140\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#e8e4d9\">Topping E2x2 \/ E4x4 interface<\/text><rect x=\"36\" y=\"146\" width=\"7\" height=\"18\" rx=\"2\" fill=\"#3fae84\"\/><text x=\"51\" y=\"160\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#a39d91\">\u2248 1 \u03a9<\/text><rect x=\"664\" y=\"146\" width=\"60\" height=\"18\" rx=\"2\" fill=\"#3fae84\"\/><text x=\"656\" y=\"160\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#a39d91\" text-anchor=\"end\">\u2248 580 mW<\/text><text x=\"36\" y=\"180\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#e8e4d9\">Typical interface (Zen Go, Audient iD4)<\/text><rect x=\"36\" y=\"186\" width=\"134\" height=\"18\" rx=\"2\" fill=\"#ff9800\"\/><text x=\"178\" y=\"200\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#a39d91\">\u2248 20\u201327 \u03a9<\/text><rect x=\"712\" y=\"186\" width=\"12\" height=\"18\" rx=\"2\" fill=\"#ff9800\"\/><text x=\"704\" y=\"200\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#a39d91\" text-anchor=\"end\">\u2248 100 mW<\/text><text x=\"36\" y=\"220\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#e8e4d9\">PC onboard (Realtek)<\/text><rect x=\"36\" y=\"226\" width=\"420\" height=\"18\" rx=\"2\" fill=\"#f44336\"\/><text x=\"464\" y=\"240\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#a39d91\">\u2248 75 \u03a9<\/text><rect x=\"719\" y=\"226\" width=\"5\" height=\"18\" rx=\"2\" fill=\"#f44336\"\/><text x=\"711\" y=\"240\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#a39d91\" text-anchor=\"end\">\u2248 30 mW<\/text><text x=\"380\" y=\"268\" font-family=\"Oswald,sans-serif\" font-size=\"11\" fill=\"#8d8980\" text-anchor=\"middle\">Power is the rated maximum; conversion to a 16 \u03a9 load is approximate<\/text><\/svg><\/div>\n<p style=\"text-align: center; font-size: 0.9em; color: #aaa; margin: 10px 0 0; font-style: italic;\">The M1 headphones are a 16 \u03a9 load (constant). On the left \u2014 the source&#8217;s own output impedance (Zout): on a 16 \u03a9 load it acts as a divider, the lower the Zout, the smaller the loss. On the right \u2014 the maximum power the source delivers into this 16 \u03a9 load. A dedicated amplifier has Zout tens of times lower and power several times higher. The rated figures are real, the conversion to 16 \u03a9 is approximate; what matters is the ratio, not the exact value <span style=\"color: #8d8980;\">\u2014 &#x1f50d; click to enlarge<\/span><\/p>\n<p>On the M1 the difference in the specs is heard like this. A &#8220;weak output&#8221; is the PC onboard or an ordinary interface; a &#8220;full-fledged&#8221; one is a dedicated amplifier or an interface with an amplifier output (Topping E2x2\/E4x4).<\/p>\n<div style=\"overflow-x: auto; -webkit-overflow-scrolling: touch; margin: 22px 0;\">\n<table style=\"width: 100%; min-width: 540px; border-collapse: collapse; margin: 0;\">\n<thead>\n<tr style=\"background: rgba(212,175,55,0.2);\">\n<th style=\"padding: 12px; border: 1px solid #333; text-align: left;\">How it sounds<\/th>\n<th style=\"padding: 12px; border: 1px solid #333; text-align: left;\">Weak output<\/th>\n<th style=\"padding: 12px; border: 1px solid #333; text-align: left;\">Full-fledged output<\/th>\n<\/tr>\n<\/thead>\n<tbody>\n<tr>\n<td style=\"padding: 12px; border: 1px solid #333;\"><strong>Bass<\/strong><\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">loose, boomy, smeared<\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">tight, controlled, with a clear attack<\/td>\n<\/tr>\n<tr>\n<td style=\"padding: 12px; border: 1px solid #333;\"><strong>Hits and transients<\/strong><\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">smeared, blur together in dense passages<\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">fast and distinct<\/td>\n<\/tr>\n<tr>\n<td style=\"padding: 12px; border: 1px solid #333;\"><strong>Loudness on peaks<\/strong><\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">no headroom, distortion and clipping in loud passages<\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">keeps its headroom, the peak is not compressed<\/td>\n<\/tr>\n<tr>\n<td style=\"padding: 12px; border: 1px solid #333;\"><strong>Overall character<\/strong><\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">quiet, lifeless, flat<\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">loud, controlled, dynamic<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/div>\n<h4>When the built-in output is enough<\/h4>\n<p>For sensitive in-ear monitors (IEMs) and high-impedance over-ear models, the output of a sound card or interface is usually enough: they need voltage, not current. The difficulty is precisely with low-impedance, low-sensitivity planars like the M1: they need an output with low impedance, current headroom and a quiet noise floor. This is provided by either a dedicated amplifier or an interface with an amplifier output (Topping E2x2\/E4x4); an ordinary built-in computer output or a budget sound card \u2014 no. That is why the amplifier stands in the chain as a separate stage.<\/p>\n<p>[\/vc_column_text][\/vc_column][\/vc_row][vc_row][vc_column][vc_column_text css=&#8221;&#8221; woodmart_inline=&#8221;no&#8221; text_larger=&#8221;no&#8221;]<\/p>\n<div style=\"height: 2px; width: 44px; background: #d4af37; border-radius: 2px; margin: 58px 0 0;\"><\/div>\n<h2 id=\"trakt-usilitel\" style=\"margin: 14px 0 16px; padding: 0; scroll-margin-top: 100px;\">&#x1f39a;&#xfe0f; Amplifier<\/h2>\n<p>Why a dedicated amplifier is needed at all has been covered above. Here is the practical part: which amplifier is convenient as the hub of the chain and how to set it up.<\/p>\n<p>We recommend Topping&#8217;s L series for the four reasons below. (Using this particular manufacturer is not mandatory \u2014 you can take any amplifier you like.)<\/p>\n<ul>\n<li><strong>Sound circuitry.<\/strong> At its core are NFCA modules (Nested Feedback Composite Amplifier), the same as in the flagship A90, plus a low output impedance, important for low-impedance planars.<\/li>\n<li><strong>Practically zero distortion.<\/strong> A noise floor of about 0.3 \u00b5V, a dynamic range of 144 dB on the L30 II and 146 dB on the L70, THD+N on the order of 0.00006% \u2014 to the ear this is absolute silence, in the pauses the amplifier gives away nothing.<\/li>\n<li><strong>Broad connectivity.<\/strong> Switching the outputs turns the amplifier into a monitoring control hub \u2014 headphones and monitors on one volume knob.<\/li>\n<li><strong>Price.<\/strong> These are high-quality devices for minimal money.<\/li>\n<\/ul>\n<p>Below are two popular models.<\/p>\n<h3>Topping L30 II \u2014 the base model<\/h3>\n<p>The L30 II is the entry model of the series. Input and output are RCA, plus a 6.35 mm headphone output. There are no balanced connectors: the input is unbalanced only, over RCA. This is worth keeping in mind \u2014 in a noisy environment an unbalanced input can pick up interference. This is removed by a single power source for the chain and short cables (see the section on power). In a quiet, carefully assembled desktop chain the L30 II works cleanly.<\/p>\n<p>The L30 II is controlled by a three-position <strong>OFF \/ HPA \/ PRE<\/strong> switch. It combines the power switch and the output selection:<\/p>\n<p><img decoding=\"async\" style=\"display: block; width: 100%; height: auto; border-radius: 10px; margin: 24px 0;\" src=\"https:\/\/gear.neuropunk.ru\/wp-content\/uploads\/diagrams\/topping-L30-II.png\" alt=\"Topping L30 II\" \/><\/p>\n<div style=\"overflow-x: auto; -webkit-overflow-scrolling: touch; margin: 22px 0;\">\n<table style=\"width: 100%; min-width: 540px; border-collapse: collapse; margin: 0;\">\n<thead>\n<tr style=\"background: rgba(212,175,55,0.2);\">\n<th style=\"padding: 12px; border: 1px solid #333; text-align: left;\">Position<\/th>\n<th style=\"padding: 12px; border: 1px solid #333; text-align: left;\">What it does<\/th>\n<\/tr>\n<\/thead>\n<tbody>\n<tr>\n<td style=\"padding: 12px; border: 1px solid #333;\"><strong>OFF<\/strong><\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">Amplifier off<\/td>\n<\/tr>\n<tr>\n<td style=\"padding: 12px; border: 1px solid #333;\"><strong>HPA<\/strong><\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">Amplifier on, the signal goes to the headphones<\/td>\n<\/tr>\n<tr>\n<td style=\"padding: 12px; border: 1px solid #333;\"><strong>PRE<\/strong><\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">Amplifier on, the signal goes to the RCA output \u2014 on to the monitors<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/div>\n<p>The outputs are mutually exclusive: at any moment the sound goes either to the headphones or to the monitors. The volume of both is meanwhile controlled by a single amplifier knob.<\/p>\n<p>In PRE mode the amplifier passes the line-level signal to the monitors without amplifying it \u2014 the active monitors do the amplifying themselves.<\/p>\n<div style=\"background: rgba(212,175,55,0.1); padding: 20px; border-radius: 8px; border-left: 4px solid #d4af37; margin: 24px 0;\">\n<h4 style=\"margin-top: 0; color: #d4af37;\">&#x1f39b;&#xfe0f; Two volumes instead of one<\/h4>\n<p>Usually headphones and monitors are two independent volume sources. To switch from one to the other, the producer turns down the volume on one, turns it up on the other, tweaks it, double-checks. Every switch is fiddling with several knobs.<\/p>\n<p style=\"margin-bottom: 0;\">The L30 II removes this tedious routine, because it works as a selector. The monitors connect to the RCA output, the headphones \u2014 to the jack. The output switch toggles between them, and the volume knob is the same for everything. One click \u2014 and the sound source has changed, staying at the same volume.<\/p>\n<\/div>\n<div class=\"np-zoom\" style=\"background:#1d1b18;border:1px solid #322f2a;border-radius:10px;padding:14px;margin:30px 0 8px;\"><svg viewBox=\"0 0 720 240\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" style=\"display:block;width:100%;height:auto;\" role=\"img\" aria-label=\"Diagram: the amplifier as a monitoring switch between headphones and monitors\"><defs><marker id=\"ar\" viewBox=\"0 0 10 10\" refX=\"8\" refY=\"5\" markerWidth=\"6\" markerHeight=\"6\" orient=\"auto-start-reverse\"><path d=\"M2 1L8 5L2 9\" fill=\"none\" stroke=\"context-stroke\" stroke-width=\"1.6\" stroke-linecap=\"round\" stroke-linejoin=\"round\"\/><\/marker><\/defs><rect x=\"8\" y=\"99\" width=\"82\" height=\"44\" rx=\"8\" fill=\"#252320\" stroke=\"#4a463f\"\/><text x=\"49\" y=\"126\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"15\" fill=\"#e8e4d9\">PC<\/text><line x1=\"92\" y1=\"121\" x2=\"118\" y2=\"121\" stroke=\"#6f6a61\" stroke-width=\"2\" marker-end=\"url(#ar)\"\/><rect x=\"120\" y=\"99\" width=\"132\" height=\"44\" rx=\"8\" fill=\"#252320\" stroke=\"#4a463f\"\/><text x=\"186\" y=\"125\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"14\" fill=\"#e8e4d9\">Audio interface<\/text><line x1=\"254\" y1=\"121\" x2=\"280\" y2=\"121\" stroke=\"#6f6a61\" stroke-width=\"2\" marker-end=\"url(#ar)\"\/><rect x=\"282\" y=\"74\" width=\"152\" height=\"94\" rx=\"9\" fill=\"#2a2417\" stroke=\"#d4af37\"\/><text x=\"358\" y=\"98\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"700\" font-size=\"16\" fill=\"#fff\">Amplifier<\/text><circle cx=\"358\" cy=\"126\" r=\"15\" fill=\"#2b2a25\" stroke=\"#d4af37\"\/><circle cx=\"358\" cy=\"126\" r=\"9\" fill=\"#565550\"\/><line x1=\"358\" y1=\"126\" x2=\"358\" y2=\"116\" stroke=\"#2b2a25\" stroke-width=\"2.5\" stroke-linecap=\"round\"\/><text x=\"358\" y=\"158\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#d4af37\">one volume knob<\/text><path d=\"M434,106 C474,106 486,64 522,64\" fill=\"none\" stroke=\"#d85a30\" stroke-width=\"2.6\" marker-end=\"url(#ar)\"\/><path d=\"M434,138 C474,138 486,180 522,180\" fill=\"none\" stroke=\"#378add\" stroke-width=\"2.6\" marker-end=\"url(#ar)\"\/><text x=\"500\" y=\"52\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"13\" fill=\"#d85a30\">HPA<\/text><text x=\"500\" y=\"200\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"13\" fill=\"#378add\">PRE<\/text><rect x=\"526\" y=\"42\" width=\"150\" height=\"46\" rx=\"8\" fill=\"#252320\" stroke=\"#4a463f\"\/><text x=\"601\" y=\"70\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"15\" fill=\"#e8e4d9\">Headphones<\/text><rect x=\"526\" y=\"158\" width=\"150\" height=\"46\" rx=\"8\" fill=\"#252320\" stroke=\"#4a463f\"\/><text x=\"601\" y=\"186\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"15\" fill=\"#e8e4d9\">Monitors<\/text><text x=\"360\" y=\"228\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"12.5\" fill=\"#8d8980\">The output switch toggles between HPA and PRE \u2014 one knob sets the volume of both<\/text><\/svg><\/div>\n<p style=\"text-align: center; font-size: 0.9em; color: #aaa; margin: 10px 0 0; font-style: italic;\">The amplifier as a monitoring switch <span style=\"color: #8d8980;\">\u2014 &#x1f50d; click to enlarge<\/span><\/p>\n<h4>Setting up seamless switching<\/h4>\n<p>For the headphones and monitors to play at the same volume, and for the HPA&#x2194;PRE switch to be seamless, their levels are matched once during setup:<\/p>\n<div style=\"background: rgba(212,175,55,0.06); border: 1px solid #333; border-radius: 8px; padding: 16px 30px; margin: 22px 0;\">\n<ol style=\"margin: 0; padding-left: 18px; line-height: 1.7;\">\n<li style=\"margin: 8px 0;\">The monitor volume is turned to zero. On most studio monitors it is adjusted by a knob on the rear panel.<\/li>\n<li style=\"margin: 8px 0;\">The L30 II switch is set to HPA. The amplifier knob is used to set a comfortable volume in the headphones.<\/li>\n<li style=\"margin: 8px 0;\">The switch is set to PRE. The amplifier knob is not touched at this point \u2014 its position is fixed.<\/li>\n<li style=\"margin: 8px 0;\">The volume is raised on the monitors themselves until they play as loud as the headphones did.<\/li>\n<li style=\"margin: 8px 0;\">Done! The volume of both sources is the same, and switching between them becomes comfortable.<\/li>\n<\/ol>\n<\/div>\n<p>After these steps, in everyday work the volume of all sources is controlled by a single knob on the amplifier. This is the most convenient and ergonomic way to work in the studio, and it saves a lot of time, which any producer will appreciate.<\/p>\n<h3>Topping L70 \u2014 the extended model<\/h3>\n<p>The L70 is a model a class above. It has balanced XLR inputs in addition to RCA, balanced headphone outputs (4-pin XLR and 4.4 mm) alongside the regular 6.35 mm, and a relay-based R2R volume attenuator.<\/p>\n<p><img decoding=\"async\" style=\"display: block; width: 100%; height: auto; border-radius: 10px; margin: 24px 0;\" src=\"https:\/\/gear.neuropunk.ru\/wp-content\/uploads\/diagrams\/topping-L70.png\" alt=\"Topping L70\" \/><\/p>\n<p>Output switching on the L70 is arranged differently from the L30 II: the modes are switched by pressing and holding the volume knob for 1 sec \u2014 each press turns on the next mode in a cycle: 1) monitors (pre-out), 2) monitors and headphones at once, 3) headphones. The middle &#8220;both at once&#8221; mode is a domestic convenience (listening both in headphones and on monitors), not a production tool. The downside for work: going from headphones to monitors is not one click, as on the L30 II&#8217;s physical switch: you have to press the knob, passing through the intermediate mode.<\/p>\n<p>The volume attenuator on the L70 is a relay-based R2R: a set of resistors switched by relays. Volume control here is fully analog and does not touch the digital part of the signal. Why this is crucial \u2014 in the next section.<\/p>\n<h4>Which to choose<\/h4>\n<p>For a desktop chain with headphones the base L30 II is enough: it covers both monitor switching and the one-knob principle. The L70 is taken when you need balanced lines, the &#8220;headphones and monitors together&#8221; mode, or power headroom.<\/p>\n<h3>&#x1f525; How not to destroy the amplifier<\/h3>\n<p>The L30 II and L70 themselves are reliable units. Below is what actually destroys an amplifier, in descending order of likelihood.<\/p>\n<div style=\"background: rgba(244,67,54,0.1); padding: 20px; border-radius: 8px; border-left: 4px solid #f44336; margin: 24px 0;\">\n<h4 style=\"margin-top: 0; color: #f44336;\">&#x26a0;&#xfe0f; Power: only the original adapter<\/h4>\n<p style=\"margin-bottom: 0;\">The most common manageable &#8220;killer&#8221; of the L30 and L30 II is the wrong power supply. They run on an unusual adapter of <strong>15 V AC (alternating current)<\/strong>. Another supply \u2014 for example 5 or 12 V DC from another device (even the E30 II DAC) \u2014 burns out the regulators and chips instantly. Only the original adapter; if similar ones are lying nearby \u2014 label them. The L70 runs on an internal supply and is free of this ailment. Against mains surges, either of them is run through a power conditioner or a UPS.<\/p>\n<\/div>\n<h4>The original L30 \u2014 check the serial number<\/h4>\n<p>The very first L30 (2020) had no protection against either DC or static discharge: on an internal fault it could put DC on its output and fry both itself and the headphones, and in a dry climate it was killed by static on touch. Topping fixed this by serial number \u2014 <strong>2021 and above are safe<\/strong>, 2011 and below must not be used (they were replaced under warranty). If you are buying a used L30 specifically without the &#8220;II&#8221; \u2014 check the serial. The L30 II and L70 are already reworked versions without this ailment.<\/p>\n<h4>General connection hygiene<\/h4>\n<p>These are not frequent causes of death for these particular models, but sensible habits for any amplifier:<\/p>\n<ul>\n<li><strong>Power sequence.<\/strong> The amplifier is switched on last and off first, the volume before switching on \u2014 at minimum (covered in detail in the section on connection order).<\/li>\n<li><strong>Switching under load.<\/strong> Do not yank the headphone jack with the volume up \u2014 a partially inserted plug briefly shorts the output. Into a balanced output (XLR \/ 4.4 mm) \u2014 only a balanced cable: a &#8220;balanced\u2192unbalanced&#8221; adapter shorts a leg to ground and on balanced amplifiers can fry the output.<\/li>\n<li><strong>Gain.<\/strong> A high gain by itself does no harm (how to choose it \u2014 in the section on Gain); what harms is constant clipping.<\/li>\n<li><strong>Ventilation.<\/strong> The L70 gets noticeably warm, and the case of such amplifiers itself serves as a passive-cooling heatsink \u2014 do not cover it, do not place other devices on top, do not wedge it into a niche without airflow.<\/li>\n<li><strong>Do not short the output.<\/strong> Do not let the output connectors touch metal or each other.<\/li>\n<\/ul>\n<p>[\/vc_column_text][\/vc_column][\/vc_row][vc_row][vc_column][vc_column_text css=&#8221;&#8221; woodmart_inline=&#8221;no&#8221; text_larger=&#8221;no&#8221;]<\/p>\n<div style=\"height: 2px; width: 44px; background: #d4af37; border-radius: 2px; margin: 58px 0 0;\"><\/div>\n<h2 id=\"trakt-gain\" style=\"margin: 14px 0 16px; padding: 0; scroll-margin-top: 100px;\">&#x1f4ca; Gain setting<\/h2>\n<p>Gain is the amplification factor, switched in steps. The higher the gain, the louder the sound at the same knob position and the higher the maximum available at the output: the rated power (on the L30 II this is 3.5 W into 16 \u03a9) the amplifier delivers only at high gain \u2014 at low gain the source simply will not drive it to these levels. At the same time, the gain itself adds no current or power headroom \u2014 it only shifts the working level. That is why it is chosen to match the headphones&#8217; sensitivity (exactly how \u2014 below).<\/p>\n<div style=\"background: rgba(255,152,0,0.08); padding: 20px; border-radius: 8px; border-left: 4px solid #ff9800; margin: 24px 0;\">\n<h4 style=\"margin-top: 0; color: #ff9800;\">&#x1f697; An analogy \u2014 steering sensitivity<\/h4>\n<p style=\"margin-bottom: 0;\">Different cars have differently tuned steering: in one it is three turns lock to lock, in another one and a half. You can drive both, but with quick steering it is easier to overshoot, while with slow steering you have to turn more. Gain is the same sensitivity adjustment, only for the volume knob.<\/p>\n<\/div>\n<p>In both recommended models the gain is switched in steps:<\/p>\n<div style=\"overflow-x: auto; -webkit-overflow-scrolling: touch; margin: 22px 0;\">\n<table style=\"width: 100%; min-width: 540px; border-collapse: collapse; margin: 0;\">\n<thead>\n<tr style=\"background: rgba(212,175,55,0.2);\">\n<th style=\"padding: 12px; border: 1px solid #333; text-align: left;\">Model<\/th>\n<th style=\"padding: 12px; border: 1px solid #333; text-align: left;\">Gain positions<\/th>\n<\/tr>\n<\/thead>\n<tbody>\n<tr>\n<td style=\"padding: 12px; border: 1px solid #333;\"><strong>Topping L30 II<\/strong><\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">L: \u221214 dB  \u00b7  M: 0 dB  \u00b7  H: +16.5 dB<\/td>\n<\/tr>\n<tr>\n<td style=\"padding: 12px; border: 1px solid #333;\"><strong>Topping L70<\/strong><\/td>\n<td style=\"padding: 12px; border: 1px solid #333;\">Low: 0 dB  \u00b7  High: +13.8 dB<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/div>\n<h4>How to choose the gain<\/h4>\n<p>Gain is chosen by the headphones&#8217; sensitivity, not by their impedance: low-impedance does not mean &#8220;loud.&#8221; The rule: set the minimum gain at which there is volume to spare, and the working knob position falls into a comfortable range (roughly the middle of its travel). If you cannot get enough volume even near the top edge \u2014 go one step up in gain. Quiet sensitive models are not considered here: the chain is built around planars.<\/p>\n<p>The Neuropunk M1 is a telling example: despite the low impedance (16 \u03a9), the headphones are of moderate sensitivity, so they require noticeable amplification. In practice the M1 work comfortably at high (up to maximum) gain on both the L30 II and the L70. Thanks to the extremely low noise of the L series, high gain adds no hum.<\/p>\n<p>[\/vc_column_text][\/vc_column][\/vc_row][vc_row][vc_column][vc_column_text css=&#8221;&#8221; woodmart_inline=&#8221;no&#8221; text_larger=&#8221;no&#8221;]<\/p>\n<div style=\"height: 2px; width: 44px; background: #d4af37; border-radius: 2px; margin: 58px 0 0;\"><\/div>\n<h2 id=\"trakt-gromkost\" style=\"margin: 14px 0 16px; padding: 0; scroll-margin-top: 100px;\">&#x1f50a; Volume at each stage<\/h2>\n<p>There are several places in the chain that have volume: the computer, the audio interface, the amplifier. A properly assembled chain is arranged so that one live control remains \u2014 the amplifier knob. The rest are set once and never touched again. Each stage is examined below.<\/p>\n<h3>Computer: 97% on Windows, 100% on Mac<\/h3>\n<p>The operating system volume is kept almost at maximum. On macOS \u2014 100%. On Windows \u2014 97%, not 100%. Additionally, in the audio device properties the format is set to 24-bit. For practice this is enough; the explanation is below.<\/p>\n<h4>In detail, mechanism 1 \u2014 bit depth<\/h4>\n<p>Digital volume reduction is multiplying each sample (signal value) by a number less than one. The result must again be fitted into an integer format of a fixed bit depth to be sent to the DAC, and in this rounding part of the information is lost: roughly, every 6 dB of attenuation is a loss of about one bit of effective bit depth.<\/p>\n<p>There is an important caveat here. In modern systems \u2014 Windows from Vista on (including 10 and 11) and macOS \u2014 the internal audio chain works in a 32-bit floating-point format (<em>32-bit float<\/em>). In it, volume control is transparent, with no loss. Loss is possible only at the last step \u2014 conversion to an integer for the DAC. And here the device format decides: at 24 bits there is 48 dB of headroom, and the signal reaches the DAC at full resolution even at heavily reduced volume. At 16 bits this step becomes the bottleneck. Hence the practical action \u2014 set 24-bit in the audio device properties.<\/p>\n<p>Dithering (<em>dithering<\/em>) is a related technique. When bit depth does have to be reduced, dithering adds a specially calculated micro-noise to the signal, which smears the rounding error. Distortion correlated with the signal turns into a smooth, harmless noise floor. This is the standard way to make a bit-depth reduction clean.<\/p>\n<h4>In detail, mechanism 2 \u2014 the Windows limiter and intersample overs<\/h4>\n<p>The second mechanism is not related to bit depth and explains why on Windows exactly 97% is recommended, not 100%.<\/p>\n<p>A peak limiter is built into the Windows audio stack from Vista on \u2014 <strong>CAudioLimiter<\/strong>. Its threshold is about <code style=\"background: rgba(212,175,55,0.12); padding: 1px 6px; border-radius: 4px; font-family: monospace; color: #d4af37;\">\u22120.13 dBFS<\/code>. It is intended as protection against clipping, but on a hot signal it itself starts to nonlinearly squeeze the peaks, and this is audible as light compression distortion.<\/p>\n<p>The second reason is <strong>intersample overs<\/strong>. A digital signal is a set of samples, but the real analog signal that the DAC reconstructs is a smooth curve between them. On peaks the curve can go above the level of the samples themselves, by +0.5\u2026+3 dB above <code style=\"background: rgba(212,175,55,0.12); padding: 1px 6px; border-radius: 4px; font-family: monospace; color: #d4af37;\">0 dBFS<\/code>. At Windows volume 100% such overshoots hit the ceiling.<\/p>\n<p>Both mechanisms are removed the same way \u2014 the signal level is pulled slightly away from the ceiling. The Windows slider at 97% (it is nonlinear, and these 3% give noticeable headroom) takes the signal out of the CAudioLimiter trigger zone and leaves room for intersample overs.<\/p>\n<p>On macOS this problem does not exist as a class: Apple does not build a limiter into the system audio chain. That is why on a Mac the volume is kept at 100%.<\/p>\n<h4>This rule is about the system mixer<\/h4>\n<p>The 97% applies to sound that goes through the Windows system mixer (shared mode): system sounds, the browser, most players. It is precisely on this path that CAudioLimiter works, and it is audible as clipping at 100% \u2014 this is easy to verify by moving the system slider. A DAW set to the audio interface&#8217;s ASIO driver goes around the system mixer: the system slider does not affect it, and the level headroom is set on the project&#8217;s master bus (controlled by true-peak), not by Windows percentages.<\/p>\n<h3>Audio interface: 100%, with no digital attenuation<\/h3>\n<p>The audio interface also has volume, and in most cases it is a digital control \u2014 which means everything said about bit depth applies to it. The rule is simple: the digital part of the audio interface works with no attenuation.<\/p>\n<p>On the Antelope Zen Go it looks like this. In the mixer the Computer Playback faders are at 0 dB \u2014 no digital attenuation. The output to the amplifier goes over RCA (Line Out), and the level of this output is set by the Line Out Trim parameter in the audio interface settings (range 14\u201320 dBu). The higher the output level, the better the signal-to-noise ratio at the amplifier&#8217;s input, so the Trim is raised \u2014 but not blindly to maximum: 20 dBu is about 7.75 V, a very hot level for a domestic RCA input. The reference point is the highest Trim at which the amplifier&#8217;s input is not overloaded and its knob stays in a comfortable range. The volume from there is controlled by the amplifier.<br \/>\nThe bottom line: whatever audio interface you have \u2014 its volume should be 100%.<\/p>\n<p><img decoding=\"async\" style=\"display: block; width: 100%; height: auto; border-radius: 10px; margin: 24px 0 8px;\" src=\"https:\/\/gear.neuropunk.ru\/wp-content\/uploads\/diagrams\/zen-go-mixer.jpg\" alt=\"Antelope Zen Go mixer \u2014 Computer Playback faders at 0 dB\" \/><\/p>\n<p style=\"text-align: center; font-size: 0.9em; color: #aaa; margin: 10px 0 0; font-style: italic;\">Antelope Zen Go mixer: the Computer Playback faders are at 0 dB \u2014 there is no digital attenuation<\/p>\n<h4>How manufacturers handle this<\/h4>\n<p>Digital volume reduction is a known engineering problem, and it is solved in different ways. RME uses an internal DSP of increased bit depth (42 bits), and the control stays transparent. SSL fits DACs with a 32-bit architecture \u2014 the real effective bit depth is always lower than stated, but there is enough digital-math headroom that turning down the volume gives no audible loss. In expensive devices they fit analog relay attenuators, where the volume is controlled after the DAC and quantization is not involved at all. The takeaway for the user is one: do not touch the digital volume on the audio interface, it is set once to maximum for the line-level signal, and the control is left to the analog amplifier.<\/p>\n<h3>Amplifier: the only live control<\/h3>\n<p>The amplifier has an analog volume control \u2014 a potentiometer or, as on the L70, a relay-based R2R attenuator. Analog attenuation works after the DAC, with the finished analog signal, and does not touch bit depth. Turning the volume down here can be done with no loss. That is why the everyday control is left to the amplifier.<\/p>\n<div class=\"np-zoom\" style=\"background:#1d1b18;border:1px solid #322f2a;border-radius:10px;padding:14px;margin:30px 0 8px;\"><svg viewBox=\"0 0 680 122\" xmlns=\"http:\/\/www.w3.org\/2000\/svg\" style=\"display:block;width:100%;height:auto;\" role=\"img\" aria-label=\"Diagram: the volume mode at each stage of the chain\"><defs><marker id=\"arv\" viewBox=\"0 0 10 10\" refX=\"8\" refY=\"5\" markerWidth=\"6\" markerHeight=\"6\" orient=\"auto-start-reverse\"><path d=\"M2 1L8 5L2 9\" fill=\"none\" stroke=\"context-stroke\" stroke-width=\"1.6\" stroke-linecap=\"round\" stroke-linejoin=\"round\"\/><\/marker><\/defs><rect x=\"40\" y=\"30\" width=\"126\" height=\"56\" rx=\"8\" fill=\"#252320\" stroke=\"#4a463f\"\/><text x=\"103\" y=\"54\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"14\" fill=\"#e8e4d9\">Computer<\/text><text x=\"103\" y=\"72\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#a39d91\">97% \/ Mac 100%<\/text><rect x=\"198\" y=\"30\" width=\"126\" height=\"56\" rx=\"8\" fill=\"#252320\" stroke=\"#4a463f\"\/><text x=\"261\" y=\"54\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"14\" fill=\"#e8e4d9\">Audio interface<\/text><text x=\"261\" y=\"72\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#a39d91\">100%<\/text><rect x=\"356\" y=\"30\" width=\"126\" height=\"56\" rx=\"8\" fill=\"#2a2417\" stroke=\"#d4af37\"\/><text x=\"419\" y=\"54\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"14\" fill=\"#fff\">Amplifier<\/text><text x=\"419\" y=\"72\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#d4af37\">chain control<\/text><rect x=\"514\" y=\"30\" width=\"126\" height=\"56\" rx=\"8\" fill=\"#252320\" stroke=\"#4a463f\"\/><text x=\"577\" y=\"54\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-weight=\"600\" font-size=\"14\" fill=\"#e8e4d9\">Headphones<\/text><text x=\"577\" y=\"72\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#a39d91\">end of the chain<\/text><line x1=\"170\" y1=\"58\" x2=\"194\" y2=\"58\" stroke=\"#6f6a61\" stroke-width=\"2\" fill=\"none\" marker-end=\"url(#arv)\"\/><line x1=\"328\" y1=\"58\" x2=\"352\" y2=\"58\" stroke=\"#6f6a61\" stroke-width=\"2\" fill=\"none\" marker-end=\"url(#arv)\"\/><line x1=\"486\" y1=\"58\" x2=\"510\" y2=\"58\" stroke=\"#6f6a61\" stroke-width=\"2\" fill=\"none\" marker-end=\"url(#arv)\"\/><text x=\"103\" y=\"105\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#8d8980\">set once<\/text><text x=\"261\" y=\"105\" text-anchor=\"middle\" font-family=\"Oswald,sans-serif\" font-size=\"12\" fill=\"#8d8980\">set once<\/text><\/svg><\/div>\n<p style=\"text-align: center; font-size: 0.9em; color: #aaa; margin: 10px 0 0; font-style: italic;\">The volume mode at each stage of the chain <span style=\"color: #8d8980;\">\u2014 &#x1f50d; click to enlarge<\/span><\/p>\n<p>A chain assembled by these rules leaves the user one live control. The computer \u2014 97% or 100%, set once. The audio interface \u2014 100%, set once. From there the volume lives only on the amplifier knob. And if the amplifier also works as a monitoring switch (the section on the L30 II), then one knob controls the volume of both the headphones and the monitors.<\/p>\n<p>[\/vc_column_text][\/vc_column][\/vc_row][vc_row][vc_column][vc_column_text css=&#8221;&#8221; woodmart_inline=&#8221;no&#8221; text_larger=&#8221;no&#8221;]<\/p>\n<div style=\"height: 2px; width: 44px; background: #d4af37; border-radius: 2px; margin: 58px 0 0;\"><\/div>\n<h2 id=\"trakt-checklist\" style=\"margin: 14px 0 16px; padding: 0; scroll-margin-top: 100px;\">&#x2705; Checklist<\/h2>\n<p>A summary of the article in the form of checks. The assembled chain is run through the points once \u2014 after that it works stably.<\/p>\n<h4>Connection<\/h4>\n<ul>\n<li>The chain is assembled in order: computer \u2192 audio interface \u2192 amplifier \u2192 headphones.<\/li>\n<li>The signal cables are assembled first, then the power is connected.<\/li>\n<li>Power-up goes from source to amplifier, power-down in reverse order.<\/li>\n<\/ul>\n<h4>Power<\/h4>\n<ul>\n<li>The whole chain is powered from a single conditioner or UPS \u2014 the devices share a common ground.<\/li>\n<li>Signal cables are short and do not run parallel to power cables.<\/li>\n<li>If there is a hum around 50 Hz, check for a ground loop \u2014 single power source or the GND\/LIFT switch.<\/li>\n<\/ul>\n<h4>Lines<\/h4>\n<ul>\n<li>Long lines are balanced (XLR or TRS). For a short desktop line RCA is enough.<\/li>\n<li>The connector sets of adjacent devices match \u2014 a balanced line requires balancing at both ends.<\/li>\n<\/ul>\n<h4>Amplifier<\/h4>\n<ul>\n<li>The gain is chosen so that the working volume falls in the middle of the knob&#8217;s travel.<\/li>\n<li>If the amplifier switches the monitoring, the headphone and monitor levels are matched once.<\/li>\n<\/ul>\n<h4>Volume<\/h4>\n<ul>\n<li>System volume: Windows \u2014 97%, macOS \u2014 100%.<\/li>\n<li>Audio device format \u2014 24-bit.<\/li>\n<li>The audio interface works with no digital attenuation: faders at 0 dB, output trim raised to maximum, 100%.<\/li>\n<li>Everyday volume control \u2014 only on the amplifier knob.<\/li>\n<\/ul>\n<p style=\"font-size: 1.1em; margin-top: 24px; padding: 18px 22px; background: rgba(76,175,80,0.1); border-left: 4px solid #4caf50; border-radius: 4px;\">A chain assembled by these points does not lose signal quality at the junctions between the stages of the chain and leaves one live control in operation. This is its maximum effective working state.<\/p>\n<p>[\/vc_column_text][\/vc_column][\/vc_row]<\/p>\n<\/div>","protected":false},"excerpt":{"rendered":"<p>[vc_row][vc_column][vc_column_text css=&#8221;&#8221; woodmart_inline=&#8221;no&#8221; text_larger=&#8221;no&#8221;] The chain &#8220;computer \u2014 audio interface \u2014 amplifier \u2014 headphones&#8221; is the basic signal chain of<\/p>\n","protected":false},"author":1,"featured_media":13404,"comment_status":"open","ping_status":"open","sticky":false,"template":"","format":"standard","meta":{"footnotes":""},"categories":[136,180],"tags":[],"class_list":["post-13397","post","type-post","status-publish","format-standard","has-post-thumbnail","hentry","category-bez-kategorii","category-rukovodstvo"],"_links":{"self":[{"href":"https:\/\/gear.neuropunk.ru\/en\/wp-json\/wp\/v2\/posts\/13397","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/gear.neuropunk.ru\/en\/wp-json\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/gear.neuropunk.ru\/en\/wp-json\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/gear.neuropunk.ru\/en\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/gear.neuropunk.ru\/en\/wp-json\/wp\/v2\/comments?post=13397"}],"version-history":[{"count":2,"href":"https:\/\/gear.neuropunk.ru\/en\/wp-json\/wp\/v2\/posts\/13397\/revisions"}],"predecessor-version":[{"id":13403,"href":"https:\/\/gear.neuropunk.ru\/en\/wp-json\/wp\/v2\/posts\/13397\/revisions\/13403"}],"wp:featuredmedia":[{"embeddable":true,"href":"https:\/\/gear.neuropunk.ru\/en\/wp-json\/wp\/v2\/media\/13404"}],"wp:attachment":[{"href":"https:\/\/gear.neuropunk.ru\/en\/wp-json\/wp\/v2\/media?parent=13397"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/gear.neuropunk.ru\/en\/wp-json\/wp\/v2\/categories?post=13397"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/gear.neuropunk.ru\/en\/wp-json\/wp\/v2\/tags?post=13397"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}