Re: DIY thoughts of the day
Posted: Tue Feb 18, 2020 11:41 am
This is a quote i found (not from a forum)
8) Some speaker companies that tell the consumer their speakers use the simplest crossovers possible to preserve phase coherence and that they build better drivers to match each other for optimal integration.
In an ideal world, it may be possible to design a linear phase coherent loudspeaker system with a moderately complex series first order crossover by implementing high quality low Q drivers and crossover elements in slanted transmission line enclosures. However, in reality, many of these companies who claim phase coherence are using poor quality OEM metal cone drivers that have harsh break-up modes. These types of drivers require more than just a first order crossover to eliminate these break-up modes, and do nothing to address the enclosure type and baffle alignment to linearize the system's response.
In addition, it is usually cost prohibitive for many manufacturers to offer a properly designed loudspeaker at a competitive price using this approach. In reality, there are many variables such as cabinet properties, baffle alignment, driver sensitivity, etc, that have a synergistic affect sometimes requiring additional compensation in the crossover design or enclosure design for optimization. There are also inherent trade-offs to designing these type of speakers (i.e. drivers firing at the listening position off-axis, limited vertical dispersion and power handling, etc).
Many loudspeaker manufacturers and experts today consider proper phase coherent speakers to be somewhat of a myth considering the limiting factors of room acoustics, listening position, and quality of the source, and may also choose not to implement these type of designs for commerical considerations or to avoid compromising the design of the product.
8) Some speaker companies that tell the consumer their speakers use the simplest crossovers possible to preserve phase coherence and that they build better drivers to match each other for optimal integration.
In an ideal world, it may be possible to design a linear phase coherent loudspeaker system with a moderately complex series first order crossover by implementing high quality low Q drivers and crossover elements in slanted transmission line enclosures. However, in reality, many of these companies who claim phase coherence are using poor quality OEM metal cone drivers that have harsh break-up modes. These types of drivers require more than just a first order crossover to eliminate these break-up modes, and do nothing to address the enclosure type and baffle alignment to linearize the system's response.
In addition, it is usually cost prohibitive for many manufacturers to offer a properly designed loudspeaker at a competitive price using this approach. In reality, there are many variables such as cabinet properties, baffle alignment, driver sensitivity, etc, that have a synergistic affect sometimes requiring additional compensation in the crossover design or enclosure design for optimization. There are also inherent trade-offs to designing these type of speakers (i.e. drivers firing at the listening position off-axis, limited vertical dispersion and power handling, etc).
Many loudspeaker manufacturers and experts today consider proper phase coherent speakers to be somewhat of a myth considering the limiting factors of room acoustics, listening position, and quality of the source, and may also choose not to implement these type of designs for commerical considerations or to avoid compromising the design of the product.