feat: remove logseq stuff
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# Ohms Law
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Solve for voltage:
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$\displaystyle V = \frac{I}{R}$
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*Solve for resistance:*
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$R = \frac{V}{I}$
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_Solve for current_
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$$
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\begin{flalign}
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I & = \frac{V}{R} &
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\end{flalign}
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$$
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# Resistors in Series
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$R = R1 + R2 + R3 ...$
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# Resistors in Parallel
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$$
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\begin{flalign}
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&\frac{1}{R} = \frac{1}{R1} + \frac{1}{R2} + \frac{1}{R3} ... &\\
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\\
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&\textit{For two resistors in parallel:} &\\
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\\
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&R = \frac{R1 * R2}{R1 + R2} &\\\
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\end{flalign}
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$$
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***Tip:***
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If resistors of the same value are in parallel the total resistance is a single resistor divided by the amount if resistors.
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## Thevenin’s Theorem
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States that it is possible to simplify any linear circuit, no matter how complex, to an equivalent circuit with just a single voltage source and series resistance connected to a load.
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# Kirchhoff's Law
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## Conservation of Charge (First Law)
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All current entering a node must also leave that node
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$$
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\begin{flalign}
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\sum{I_{IN}} = \sum{I_{OUT}}&&
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\end{flalign}
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$$
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**Example:**
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For this circuit kirchhoffs law states that:
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$\displaystyle i1 = i2 + i3 + i4$
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## Conservation of Energy (Second Law)
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All the potential differences around the loop must sum to zero.
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$\displaystyle \sum{V} = 0$
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## Capacitors in Series
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$\displaystyle \frac{1}{C_{t}} = \frac{1}{C_{1}}+\frac{1}{C_{2}}+\frac{1}{C_{3}} ...$
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### Impedance in a Circuit
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$$
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\begin{flalign}
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&Z = \sqrt{R^2 + X^2} &\\\
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\\
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&X = X_{L} - X_{C} \\
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\end{flalign}
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$$
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@ -1,43 +0,0 @@
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# Glossary
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## Impedance (Z)
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In [electrical engineering](https://en.wikipedia.org/wiki/Electrical_engineering "Electrical engineering"), **impedance** is the opposition to [alternating current](https://en.wikipedia.org/wiki/Alternating_current "Alternating current") presented by the combined effect of [resistance](https://en.wikipedia.org/wiki/Electrical_resistance "Electrical resistance") and [reactance](https://en.wikipedia.org/wiki/Electrical_reactance "Electrical reactance") in a [circuit](https://en.wikipedia.org/wiki/Electrical_circuit "Electrical circuit").
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[[formulas#Impedance in a Circuit]]
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## Voltage (V)
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**Voltage**, **electric potential difference**, **electric pressure** or **electric tension** is the difference in [electric potential](https://en.wikipedia.org/wiki/Electric_potential "Electric potential") between two points.
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## Resistance (R)
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The **electrical resistance** of an object is a measure of its opposition to the flow of [electric current](https://en.wikipedia.org/wiki/Electric_current "Electric current").
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## Capacitance (C)
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**Capacitance** is the ability of a component or circuit to collect and store energy in the form of an electrical charge.
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## Inductance (L)
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**Inductance** is the tendency of an [electrical conductor](https://en.wikipedia.org/wiki/Electrical_conductor "Electrical conductor") to oppose a change in the [electric current](https://en.wikipedia.org/wiki/Electric_current "Electric current") flowing through it.
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## Current (I)
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How many electrons flow through a circuit in a second
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## Polarity
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Means if a component is symmetric or not
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Polarised means that a component is not symmetric
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## LED
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Anode - The shorter Leg
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Cathode - The longer Leg
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## Diode
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## Anode
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The positive end of a diode
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## Cathode
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The negative end of a diode
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## Conventional Current Flow
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When electricity was discovered people thought the electrons flow from the positive terminal to the negative, in actuality they flow in the opposite direction, but it is still possible to calculate the flow with the old way.
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## Reactive Components
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A component is a **reactive component** when it resists to changes in current or voltage.
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## Farad
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Measures capacitance, the ability of a body to store an electrical charge.
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1 Farad = the ability to store 1 couloumb
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Term | Symbol | Weight
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-----------|----|------
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Picofarad | pW | $10^{-12}$
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Nanofarad | nF | $10^{-9}$
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Microfarad | $\micro$F | $10^{-6}$
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Milifarad | mF | $10^{-3}$
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Farad | F | $10^0$
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Kilofarad | kF | $10^{3}$
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## Couloumb
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1 coulomb is the electric charge transported within one second through the cross-section of a conductor in which an electric current of the strength of 1 ampere flows.
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## Henry
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Measures electrical Inductance
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$\displaystyle V(t)=L{\frac {dI}{dt}}$
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## Volts
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Measures electric potential
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## Amperes
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Measures electric current
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## Ohms
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Measures resistance
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Term | Symbol | Weight
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-----------|----|------
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Nanoohm | n$\ohm$ | 10-9
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Microohm | $\micro \ohm$ | $10^{-6}$
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Milliohm | m$\ohm$ | $10^{-3}$
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Ohm | $\ohm$ | $10^{0}$
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Kiloohm | k$\ohm$ | $10^{3}$
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Megaohm | M$\ohm$ | $10^{6}$
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Gigaohm | G$\ohm$ | $10^{9}$
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## Hertz
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Measures frequency
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Term | Symbol | Weight
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----------|------- | -----
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Hertz | Hz | $10^0$
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Kilohertz | kHz | $10^{3}$
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Megahertz | mHz | $10^6$
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## Watt
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Measures Power
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$Power = V * I = \frac{V^{2}}{R} = I^{2}R$
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Joules per Second
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Term | Symbol | Weight
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-----------|----|------
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Nanowatt | nW | $10^{-9}$
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Microwatt | $\micro$W | $10^{-6}$
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Milliwatt | mW | $10^{-3}$
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Watt | W | $10^{0}$
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Kilowatt | kW | $10^{3}$
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Megawatt | MW | $10^{6}$
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Gigawatt | GW | $10^{9}$
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**Examples:**
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Device | Power
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-------|----------
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Arduino| 167mW
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Laptop | 1.5W
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House | 2.2kW
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@ -1,31 +0,0 @@
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# Roadblocks
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## ~~ Nested tmux sessions ~~
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Adding this:
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```config
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RequestTTY true
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RemoteCommand tmux new -A -s ssh
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```
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to the ssh config if the specific hosts will automatically start tmux when connected
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If i ssh into a remote machine with tmux started as well I have some problems:
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- ~~ Duplicate tmux bar ~~
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- ~~ Shortcuts don't work in remote ~~
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- This works by hitting the prefix key twice, e.g. ctrl-a-a
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## ~~ Debian Gnome sometimes comma key doesn't work ~~
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Has not happened in a while
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## ~~ Neovim shortcut to comment out ~~
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Fixed this by installing the NerdCommenter Plugin
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## ~~ Neovim Auto fix problems shortcut + hover window ~~
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## ~~ Better git merging in Neovim, like in VScode ~~
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## ~~ Copying between neovim, tmux and ssh sessions does not work ~~
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## Learn how to use splits and buffers in neovim
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## Fix the dictionary for neovim ltex-ls
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@ -1 +0,0 @@
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{}
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