Guidebook typo fixes (#31159)

* Fixed typo: access --> accessed

* Fixed typo: 'access restricted' --> 'access-restricted'

* Fixed typo: added 'be'

* Fixed typo: added 'a'

* Fixed typo: 'Asssistants' --> 'Assistants'

* Fixed typo: 'overpressure' --> 'overpressurize'

* Fixed typo: 'outisde' --> 'outside'

* Fixed typo: added a comma

* Fixed typo: added a comma

* Fixed typo: 'aformentioned' --> 'aforementioned'

* Fixed typo: added a comma

* Fixed typo: added a comma

* Fixed typo: 'radition' --> 'radiation'

* Fixed typo: 'turing' --> 'turning'

* Fixed typo: 'appropiate' --> 'appropriate'

* Fixed typo: added 'the'

* Fixed typo: added a dot to ellipsis

* Fixed typo: 'aswell' --> 'as well'

* Fixed typo: 'permanant' --> 'permanent'

* Fixed typo: 'flammmable' --> 'flammable'

* Fixed typo: 'recommmended' --> 'recommended'

* Fixed typo: 'recipies' --> 'recipes'

* Fixed typo: 'pre-adminsitered' --> 'pre-administered'

* Fixed typo: 'resusitated' --> 'resuscitated'

* Fixed typo: 'types' --> 'type'

* Fixed typo: `someones` --> `someone's`

* Fixed typo: 'appy' --> 'apply'

* Fixed typo: added 'to'

* Fixed typo: 'CentCom' --> 'CentComm' (as per https://github.com/space-wizards/space-station-14/pull/29217)

* Fixed typo: 'emergencys' --> 'emergencies'

* Fixed typo: removed a dash

Resources/ServerInfo/Guidebook/Engineering/AccessConfigurator.xml

@@ -22,13 +22,13 @@
   ## Restrictions on changing access
   As a safety precaution, the inserted ID must possess [bold]all[/bold] of the access requirements that are currently active on the connected device in order to modify it.
 
-  For example, a device which can be access by both 'Science' and 'Medical' personnel can only by modified using an ID card that has access to [color=#a4885c]both[/color] of these departments.
+  For example, a device which can be accessed by both 'Science' and 'Medical' personnel can only by modified using an ID card that has access to [color=#a4885c]both[/color] of these departments.
   The access configurator will warn the user if the inserted ID card does not have sufficient privileges to modify a device.
 
   A device with no access requirements set, like a public access airlock, can be modified using any valid station ID card.
 
   ## Repairing damaged ID card readers
-  Syndicate agents may attempt to hack access restricted devices through the use of a [color=#a4885c]Cryptographic Sequencer (EMAG)[/color]. This nefarious tool will completely short out any ID card readers that are attached to the device.
+  Syndicate agents may attempt to hack access-restricted devices through the use of a [color=#a4885c]Cryptographic Sequencer (EMAG)[/color]. This nefarious tool will completely short out any ID card readers that are attached to the device.
 
   Engineers will need to partially de/reconstruct affected devices, and then set appropriate access permissions afterwards using the access configurator (or network configurator, for airlocks), to re-establish access restrictions.
 </Document>

Resources/ServerInfo/Guidebook/Engineering/AirlockSecurity.xml

@@ -2,7 +2,7 @@
   # Airlock Upgrades
   It is not uncommon for plucky individuals to try and bypass an airlock by meddling with its internal wiring.
 
-  Fortunately, certain countermeasures can installed into airlocks to inconvenience any would-be trespassers.
+  Fortunately, certain countermeasures can be installed into airlocks to inconvenience any would-be trespassers.
 
   ## Medium security airlocks
   The most basic form of intrusion deterrence is to install a secured steel plating that will prevent access to internal wiring of the airlock.

Resources/ServerInfo/Guidebook/Engineering/Atmospherics.xml

@@ -22,7 +22,7 @@
     <GuideEntityEmbed Entity="GasVentPump"/>
     <GuideEntityEmbed Entity="GasVentScrubber"/>
   </Box>
-  During standard operation, if a normal vent detects that the outside environment is space, it will automatically cease operation until a minimum pressure is reached to avoid destruction of useful gasses. This can be fixed by pressurizing the room up to that minimum pressure by refilling it with gas canister (potentially multiple, if the room is of significant size).
+  During standard operation, if a normal vent detects that the outside environment is space, it will automatically cease operation until a minimum pressure is reached to avoid destruction of useful gasses. This can be fixed by pressurizing the room up to that minimum pressure by refilling it with a gas canister (potentially multiple, if the room is of significant size).
 
   Should you encounter a situation where scrubbers aren't cleaning a room fast enough (and the "Siphon" functionality still cannot keep up), employ portable scrubbers by dragging them to the affected location and wrenching them down. They work much faster than typical scrubbers and can clean up a room quite quickly. Large spills may require you to employ multiple.
   <Box>

Resources/ServerInfo/Guidebook/Engineering/Engineering.xml

@@ -3,7 +3,7 @@
 [color=#f39f27]Engineering[/color] is a combination of construction work, repair work, maintaining a death machine that happens to produce power, and making sure the station contains breathable air.
 
 ## Personnel
-[color=#f39f27]Engineering[/color]'s staff is made up of Technical Asssistants, Station Engineers and Atmospheric Technicians. Engineering is run by the Chief Engineer.
+[color=#f39f27]Engineering[/color]'s staff is made up of Technical Assistants, Station Engineers and Atmospheric Technicians. Engineering is run by the Chief Engineer.
 
   <Box>
     <GuideEntityEmbed Entity="ToyFigurineEngineer" Caption="Engineer"/>

Resources/ServerInfo/Guidebook/Engineering/Fires.xml

@@ -13,13 +13,13 @@
   As a result, there are three main options to repressurize the affected area:
 
   1. Assuming distro vents and pipes have not been destroyed in some unfortunate accident, you may set surrounding air alarms to the "Fill" setting. This will cause connected air vents to override their safeguards and begin repressurizing the area.
-    - Be aware this setting also allows vents to OVERpressure a room, so this process must be monitored at all times.
+    - Be aware this setting also allows vents to OVERpressurize a room, so this process must be monitored at all times.
 
   2. Another option is to open any firelocks that were engaged in response to the original spacing. This will cause the pressure to equalize between both areas.
     - This option generally causes more firelocks to engage in the surrounding area, potentially causing disruptions or making the second area unsafe for station crew.
 
   3. The final option is to bring a canister into the spaced area and open its release valve. An air canister at 4500kpa can fully repressurize around 20-30 tiles before running out of gas.
-    - This option requires the canister be brought in from outisde (generally atmos) which can be slow and time consuming depending on the situation.
+    - This option requires the canister be brought in from outside (generally atmos), which can be slow and time consuming depending on the situation.
 
 
   ## Fires

Resources/ServerInfo/Guidebook/Engineering/NetworkConfigurator.xml

@@ -9,7 +9,7 @@
   ## List Mode
   In list mode you can click on network devices to save them on the configurator and then on a network device that has a device list like the [color=#a4885c]Air Alarm[/color].
 
-  When clicking on a device like the Air Alarm, a UI will open displaying the list currently saved on the device and buttons to manipulate that list.
+  When clicking on a device like the Air Alarm, a UI will open, displaying the list currently saved on the device and buttons to manipulate that list.
 
   You can:
   - Replace the current list with the one saved on the configurator
@@ -27,11 +27,11 @@
 
   Now, you can either click [color=gray]Link Defaults[/color] to link the default ports for a source + sink combination, or press on a source port and then a sink port to connect them.
 
-  An example of a default link for the aformentioned combinaton of devices would be:
+  An example of a default link for the aforementioned combinaton of devices would be:
   <Box>
     [color=cyan]Pressed 🠒 Toggle[/color]
    </Box>
-  When you're done connecting the ports you want you can click on [color=gray]OK[/color] to close the UI.
+  When you're done connecting the ports you want, you can click on [color=gray]OK[/color] to close the UI.
 
   You can quickly link multiple devices to their default port by first clicking on a device that can be linked and then using [color=gray]Alt+Left Mouse button[/color] on the devices you want to link together.
 

Resources/ServerInfo/Guidebook/Engineering/Networking.xml

@@ -3,7 +3,7 @@
   Some devices on the station need to communicate with each other, and they do this by utilizing device networking.
   With networking, machines and devices can send arbitrary data between each other.
   There are multiple networks that get used, such as the wireless and wired network.
-  Each network device has a frequency it receives on. PDAs for example, use the frequency: [color=green]220.2[/color]
+  Each network device has a frequency it receives on. PDAs, for example, use the frequency: [color=green]220.2[/color]
 
   Note: The following operations will require use of the Network Configurator to be performed:
 

Resources/ServerInfo/Guidebook/Engineering/Singularity.xml

@@ -71,7 +71,7 @@
     <GuideEntityEmbed Entity="RadiationCollector"/>
     <GuideEntityEmbed Entity="PlasmaTank"/>
   </Box>
-  The radition collectors connect to HV cables and generate power from nearby radiation sources when turned on.
+  The radiation collectors connect to HV cables and generate power from nearby radiation sources when turned on.
   Radiation collectors require a tank full of gaseous plasma in order to operate.
   Continous radiation exposure will gradually convert the stored plasma into tritium, so replace depleted plasma tanks with fresh ones regularly to maintain a high power output.
 
@@ -84,11 +84,11 @@
   Do note that one grounding rod is not a foolproof solution; get [color=#a4885c]at least 4 rods[/color] around the containment field to make it mathematically unlikely for the tesla to escape.
   As the ball lightning zaps tesla coils, they will degrade from wear; make sure to [color=#a4885c]weld them[/color] every now and then to keep generating power.
 
-  ## Turing on the Engines
+  ## Turning on the Engines
 
   [color=red]Do not[/color] turn the PA on unless all the other subsystems are working properly and there is enough power to start the engine.
 
-  Turn power on using the PA control computer. Set the strength to an appropiate level. The higher the output stength is set on PA control computer, the bigger the singularity will be.
+  Turn power on using the PA control computer. Set the strength to an appropriate level. The higher the output stength is set on PA control computer, the bigger the singularity will be.
 
   Currently, the output power does not affect the ball lightning, beyond giving the ball lightning extra orbs around it.
 

Resources/ServerInfo/Guidebook/Engineering/TEG.xml

@@ -3,7 +3,7 @@
 
   The TEG generates power by exchanging heat between hot and cold gases. On the station, hot gas is usually created by burning plasma, and an array of heat-exchanging pipes in space radiates away heat to cool down circulated gases.
 
-  The TEG relies heavily on atmospherics piping. The only truly special component about it is the generator core and circulators; the rest is all off-the-shelf atmospherics equipment. Note that while the exact layout may vary significantly depending on station, the general components and setup are usually the same.
+  The TEG relies heavily on atmospherics piping. The only truly special component about it is the generator core and circulators; the rest is all off-the-shelf atmospherics equipment. Note that while the exact layout may vary significantly depending on the station, the general components and setup are usually the same.
 
   ## Generator
 
@@ -54,7 +54,7 @@
     <GuideEntityEmbed Entity="GasThermoMachineHeaterEnabled" Caption="" Rotation="180" Margin="0"/>
   </Box>
   - The Gas input is pretty self-explanatory; this is where you will input the O2-Plasma mix to be burnt. A 2:1 (67/33) ratio of Oxygen to Plasma is recommended for the hottest burn.
-  - The High-pressure pump serves 2 purposes; first, it prevents the burn from backwashing into the supply pipe, which would be.. bad, for many reasons. Second, it maintains a positive pressure in the following pipe segment, which is important to allow the burn to continue, especially since hot gases expand.
+  - The High-pressure pump serves 2 purposes; first, it prevents the burn from backwashing into the supply pipe, which would be... bad, for many reasons. Second, it maintains a positive pressure in the following pipe segment, which is important to allow the burn to continue, especially since hot gases expand.
   - The Pipe segment is where the burn actually occurs; to start it off, one can use a heater to increase the temperature up to the ignition temperature of Plasma. Afterwards, the reaction should be self-sustaining, so long as the Pressure and Moles supplied remains high enough. [color=#a4885c]Be warned[/color]; if you wish to remove the heater, it will carry some of this superheated gas with it, transferring it to the next pipenet you connect it to. Best to space the gas through a space vent, if you must.
   - The Low-pressure pump (whose pressure should be [italic]slightly lower[/italic] than the input pump) prevents [italic]all[/italic] the gas from passing through the circulator, which could result in the loss of the Moles required to sustain a burn.
   - The Circulator is where this generated heat will flow to the cold loop; afterwards, feel free to space the waste gases.
@@ -106,7 +106,7 @@
   The space vent (designated as a blast door to space on one side of the burn chamber) allows waste gases to be expelled and destroyed. Open this every now and then to keep the pressure under control, or to space excess input gas.
 
   The scrubber array filters out all the burnt gasses and sends them through the TEG. Note that using default settings on the scrubbers is a bad idea, as valuable plasma will be filtered out too.
-  Instead, use a network configurator to connect all the scrubbers to a nearby air alarm, and set the air alarm's scrubber settings to scrub everything except Oxygen and Plasma, and to siphon air aswell. This ensures that as much heat as available can be collected and sent to the TEG.
+  Instead, use a network configurator to connect all the scrubbers to a nearby air alarm, and set the air alarm's scrubber settings to scrub everything except Oxygen and Plasma, and to siphon air as well. This ensures that as much heat as available can be collected and sent to the TEG.
 
   Note that these are just two of many ways you can setup the hot loop; [color=#a4885c]feel free to mix and match setups as needed![/color] Volume pumps in replacement of pressure pumps, radiator loops for heat collection, or even a Pyroclastic anomaly to provide said heat! The stars are the limit!
 
@@ -118,7 +118,7 @@
 
   ## The Water Cooler
 
-  An equally naive method as the Pipe Burn, this simply involves taking some useless gas (in this case, Water Vapour) and flowing it through the TEG and into space. It's dirt-cheap and simple, at the cost of efficiency and permanant loss of gas.
+  An equally naive method as the Pipe Burn, this simply involves taking some useless gas (in this case, Water Vapour) and flowing it through the TEG and into space. It's dirt-cheap and simple, at the cost of efficiency and permanent loss of gas.
 
   Setting this up is so simple, even Hamlet could manage it. Just take an output of a gas (here, Water Vapour), send it through the Cold side of the TEG, and then vent it into space.