I have found that 1/r2 is a good shielding; put the power supply in another room and run dc to the stereo. I also found that using dc on the filaments of the preamp tubes (12AX7 hi-mu triodes) helped.Lancelot59 said:That does seem a bit trickier.
I ask because I have plans for a few summer projects to keep myself amused. One if them is a stereo system, and I want to isolate as much noise from the power supply as I can.
I figure instead of building a cage around the rest of the system to keep fields out, why not just trap the fields in the power supply?
Another is a Power bus that has circuits controlled by Triacs, and I want to keep the fields trapped in the power cords, and the device itself so that noise doesn't enter my microphone when I record.
An Inverse Faraday Cage is a structure designed to contain magnetic fields instead of blocking them. It is the opposite of a traditional Faraday Cage, which is designed to block electromagnetic fields.
An Inverse Faraday Cage works by using a conductive material, such as copper, to create a closed loop that redirects the magnetic field around the outside of the cage. This prevents the magnetic field from penetrating the interior of the cage.
An Inverse Faraday Cage has various applications, including in magnetic shielding for sensitive electronic equipment, containment of magnetic fields in research and medical facilities, and in creating controlled environments for experiments and testing.
Using an Inverse Faraday Cage can provide protection for sensitive equipment and devices from external magnetic fields. It can also prevent interference from external magnetic fields, allowing for more accurate measurements and experiments.
While an Inverse Faraday Cage can be effective in containing magnetic fields, it may not completely block all magnetic fields. Additionally, it can be expensive and difficult to construct, and may require regular maintenance to ensure its effectiveness.