As mentioned previously, you won’t be able to achieve the above mentioned levels of super high efficiency (super high energy conversion) without developing some form of power converter to convert electrical energy into magnetic field. That’s where the superconductor comes in. Supercomposites have a very high magnetic energy conversion efficiency (MECE), even higher than the standard silicon materials that we are using today. They are also relatively inexpensive, making them an ideal material for power converters.
Although many studies have been published on superconductors, most of them focus on specific applications: in electronics, as used to make transistors. So here I will instead focus on their use for high accuracy magnetoelectric field sensors, as described in the video above.
Using superconductors in power converters has other advantages. First of all, they are extremely cheap, they take up very little space, and they can be recycled, using the magnetic field. Secondly, they are very light, so they can be used in large quantities.
A superconducting voltage/current converter
We will now use the diagram below as an example of a typical magnetic field sensor. If you look at the schematic a lot more, you will see that the capacitor is connected to one side of the field and the collector (the other side) is connected to the other side of the field. The signal flowing through that is a voltage/current of DC (direct current). The voltage/current being supplied is the voltage over time. There are two major problems with this setup: a) the power is from the battery (if any) and the power supply is always directly connected to the battery. And b) superconductors are very brittle, so most of the current coming into the sensor is lost in a few seconds.
To make the solution, we are going to use a superconducting current/voltage converter. A superconducting current/voltage converter (SCVD) is a voltage divider (VDC) that can divide a current to make two voltages. Using SCVD allows us to split the AC current by dividing by the capacitor. We will show off how it works in the next section.
What we are going to do is take the current going into the sensor and apply voltage across it. We then convert the voltage we get in, by using the same kind of super capacitor we are using in a voltage divider. At the end of the circuit, we have two volt
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