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title = "Grounding and shielding: circuits and interference"
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author = ["Thomas Dehaeze"]
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draft = false
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Reference
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2021-02-06 16:00:01 +01:00
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: ([Morrison 2016](#org7039b1d))
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2021-02-06 11:14:08 +01:00
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Author(s)
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: Morrison, R.
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Year
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: 2016
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## Voltage and Capacitors {#voltage-and-capacitors}
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2021-02-06 11:17:27 +01:00
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<div class="sum">
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<div></div>
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2021-02-06 11:14:08 +01:00
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This first chapter described the electric field that is basic to all electrical activity.
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The electric or \\(E\\) field represents forces between charges.
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The basic charge is the electron.
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When charges are placed on conductive surfaces, these forces move the charges to positions that store the least potential energy.
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This energy is stored in an electric field.
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The work required to move a unit of charge between two points in this field is the voltage between those two points.
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Capacitors are conductor geometries used to store electric field energy.
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The ability to store energy is enhanced by using dielectrics.
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It is convenient to use two measures of the electric field.
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The field that is created by charges is called the \\(D\\) field and the field that results in forces is the \\(E\\) field.
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A changing \\(D\\) field represents a displacement current in space.
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This changing current has an associated magnetic field.
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This displacement current flows when charges are added or removed from the plates of a capacitor.
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</div>
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2021-02-06 11:59:30 +01:00
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### Introduction {#introduction}
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<a id="org40e5e37"></a>
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2021-02-06 14:03:17 +01:00
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{{< figure src="/ox-hugo/morrison16_field_conf.png" caption="Figure 1: Field configurations around a shieded conductor" >}}
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2021-02-06 11:59:30 +01:00
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2021-02-06 11:14:08 +01:00
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## Magnetics {#magnetics}
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2021-02-06 16:00:01 +01:00
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<div class="sum">
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<div></div>
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This chapter discusses magnetic fields.
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As in the electric field, there are two measures of the same magnetic field.
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The \\(H\\) field is the direct result of current flow.
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The \\(B\\) field is the force of induction field that operates motors and transformers.
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As in the electric field, the magnetic field is represented by field lines.
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The \\(B\\) field lines are continuous and form closed curves.
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The \\(H\\) field flux lines follow the \\(B\\) field lines but change intensity depending on the permeability of the material in the magnetic path.
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In this chapter, the movement of electrical energy into inductors or across transformers is discussed.
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This extends the ideas that both fields are need to move energy.
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Both electric and magnetic fields are need in transformers action or to place energy into an inductor.
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It will be shown that iron cores in transformers reduce the magnetizing current so that transformer action is practical at power frequencies.
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The idea that a changing electric field creates both a displacement current and a magnetic field discussed in Chapter 1.
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In this chapter, it is shown that a changing magnetic field produces both an electric field and voltages.
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Both fields must be in transition before an electrical energy can be moved.
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</div>
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2021-02-06 11:14:08 +01:00
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## Digital Electronics {#digital-electronics}
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### 3.1. Introduction {#3-dot-1-dot-introduction}
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### 3.2. The Transport of Electrical Energy {#3-dot-2-dot-the-transport-of-electrical-energy}
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### 3.3. Transmission Lines–Introduction {#3-dot-3-dot-transmission-lines-introduction}
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### 3.4. Transmission Line Operations {#3-dot-4-dot-transmission-line-operations}
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## Analog Circuits {#analog-circuits}
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## Utility Power and Facility Grounding {#utility-power-and-facility-grounding}
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## Radiation {#radiation}
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## Shielding from Radiation {#shielding-from-radiation}
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## Bibliography {#bibliography}
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2021-02-06 16:00:01 +01:00
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<a id="org7039b1d"></a>Morrison, Ralph. 2016. _Grounding and Shielding: Circuits and Interference_. John Wiley & Sons.
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