@audiokinesis, "@trelja, can you tell me what the actual mechanisms are by which crossover parts count and/or conventional crossover topologies constrain dynamics? There may be effects I’m unaware of that are worth taking into account, even if they aren’t necessarily the primary cause of compression. You may be correct that a steep crossover slope constrains dynamics, but can you tell me why? The "why’s" interest me a great deal."
Thank you, Duke. The "why’s" interest me a great deal, as well! That’s where the fun and advancement come from. I believe the issue under consideration is actually quite a simple thing. To make the point let’s go back to Electronics 101.
Resistors represent a fundamental component in the toolbox. Resistors reduce voltage, reduce gain, reduce dynamics. We use that to our advantage. When a mother, wife, roommate, dorm captain, guy sitting next to us on the bus, police officer, etc. tell us to turn the sound down, we make things quieter by adding more resistance to the respective audio signal, and (hopefully) restore the peace. We reduced the volume / dynamics from an objectionable level to something others can accept. That’s obviously what the volume control on a preamplifier does. We also use resistance to reduce the voltage through the succeeding stages of our power supplies to suit the needs and limitations of the downstream components. Likewise, as tweeters traditionally play louder than woofers, we use resistance to lower the tweeter’s voltage which translates to volume and dynamics to some level closer to the woofer in order to balance the sound between the two drivers out, and produce an overall better result. Resistors, no matter how small cannot and do not add voltage or volume or dynamics, and they cannot and do not leave the voltage or volume or dynamics unchanged. Resistors, no matter how small, reduce the voltage, reduce volume, reduce dynamics. Add resistors, no matter how small, to loudspeaker crossovers, and we reduce volume / dynamics of that loudspeaker.
Inductors are another fundamental electronic component, and typically a part of the crossovers discussed in this thread. They block part of the musical signal from getting to a driver, intentionally so, as we cross over from one driver to another. Every piece of wire, regardless of its elemental composition or length, has resistance. Increase the length of wire and we increase its resistance. Longer wires have measurable and meaningful levels of resistance. Inductors are made from a long (can be 50’, 100’, or even 300’) piece of wire, coiled upon itself. In fact, one specification of an inductor will be its resistance. In other words, on some level since an inductor consists of a long piece of wire, an inductor is a resistor. Again, resistors reduce dynamics. Use an inductor, and you’ve increased resistance and reduced dynamics. Moving from the typical 16 or 18AWG to an 8 or 12AWG often brings the comment of the obvious increase in dynamics and slam. Why? Because its resistance has decreased. Not to the zero not having the inductor at all would represent, but it shows adding components adds resistance which reduces volume and dynamics, and vice versa.
Capacitors are another fundamental electronic component, and like inductors, usually a part of crossovers discussed in this thread, and also block part of the musical signal from getting to a driver, intentionally so, as we cross over from one driver to another. Capacitors also have resistance, commonly noted as ESR (equivalent series resistance). No need to repeat the same statements as inductors, other than to say add a capacitor and we’ve added resistance which reduces volume and dynamics.
The number and position of inductors and capacitors in the crossover leg in the typical parallel network determines its slope. Second order crossovers have an additional inductor and capacitor from a first order crossover. Third order crossovers have another inductor and capacitor from a second order crossover, and so on. Like for like, fourth order crossovers have more inductors and capacitors than third order crossovers, which have more inductors and capacitors than second order crossovers, which have more inductors and capacitors than first order crossovers. Beyond that, there are compensation networks, made up of additional resistors, inductors, and capacitors a loudspeaker designer may add to the basic layout to suit their design goals. These will also to varying degrees, add resistance to the overall crossover. Additional components work in an additive, in terms of resistance, manner. As previously stated multiple times, adding resistance reduces volume and reduces dynamics.
Again, crossover slope absolutely rob dynamics, substantially so
Thank you, Duke. The "why’s" interest me a great deal, as well! That’s where the fun and advancement come from. I believe the issue under consideration is actually quite a simple thing. To make the point let’s go back to Electronics 101.
Resistors represent a fundamental component in the toolbox. Resistors reduce voltage, reduce gain, reduce dynamics. We use that to our advantage. When a mother, wife, roommate, dorm captain, guy sitting next to us on the bus, police officer, etc. tell us to turn the sound down, we make things quieter by adding more resistance to the respective audio signal, and (hopefully) restore the peace. We reduced the volume / dynamics from an objectionable level to something others can accept. That’s obviously what the volume control on a preamplifier does. We also use resistance to reduce the voltage through the succeeding stages of our power supplies to suit the needs and limitations of the downstream components. Likewise, as tweeters traditionally play louder than woofers, we use resistance to lower the tweeter’s voltage which translates to volume and dynamics to some level closer to the woofer in order to balance the sound between the two drivers out, and produce an overall better result. Resistors, no matter how small cannot and do not add voltage or volume or dynamics, and they cannot and do not leave the voltage or volume or dynamics unchanged. Resistors, no matter how small, reduce the voltage, reduce volume, reduce dynamics. Add resistors, no matter how small, to loudspeaker crossovers, and we reduce volume / dynamics of that loudspeaker.
Inductors are another fundamental electronic component, and typically a part of the crossovers discussed in this thread. They block part of the musical signal from getting to a driver, intentionally so, as we cross over from one driver to another. Every piece of wire, regardless of its elemental composition or length, has resistance. Increase the length of wire and we increase its resistance. Longer wires have measurable and meaningful levels of resistance. Inductors are made from a long (can be 50’, 100’, or even 300’) piece of wire, coiled upon itself. In fact, one specification of an inductor will be its resistance. In other words, on some level since an inductor consists of a long piece of wire, an inductor is a resistor. Again, resistors reduce dynamics. Use an inductor, and you’ve increased resistance and reduced dynamics. Moving from the typical 16 or 18AWG to an 8 or 12AWG often brings the comment of the obvious increase in dynamics and slam. Why? Because its resistance has decreased. Not to the zero not having the inductor at all would represent, but it shows adding components adds resistance which reduces volume and dynamics, and vice versa.
Capacitors are another fundamental electronic component, and like inductors, usually a part of crossovers discussed in this thread, and also block part of the musical signal from getting to a driver, intentionally so, as we cross over from one driver to another. Capacitors also have resistance, commonly noted as ESR (equivalent series resistance). No need to repeat the same statements as inductors, other than to say add a capacitor and we’ve added resistance which reduces volume and dynamics.
The number and position of inductors and capacitors in the crossover leg in the typical parallel network determines its slope. Second order crossovers have an additional inductor and capacitor from a first order crossover. Third order crossovers have another inductor and capacitor from a second order crossover, and so on. Like for like, fourth order crossovers have more inductors and capacitors than third order crossovers, which have more inductors and capacitors than second order crossovers, which have more inductors and capacitors than first order crossovers. Beyond that, there are compensation networks, made up of additional resistors, inductors, and capacitors a loudspeaker designer may add to the basic layout to suit their design goals. These will also to varying degrees, add resistance to the overall crossover. Additional components work in an additive, in terms of resistance, manner. As previously stated multiple times, adding resistance reduces volume and reduces dynamics.
Again, crossover slope absolutely rob dynamics, substantially so