Difference between revisions of "Formulas"
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* '''Damage''' : | * '''Damage''' : | ||
− | Damage ( % ) = '''Base Damage''' x ( 1 + '''Basic/Advanced | + | Damage ( % ) = '''Base Damage''' x ( 1 + '''[[Basic robotics|Basic]]/[[Advanced robotics]]''' x 0.05 + '''Basic/Advanced Weapon''' ) x ( 1 + [[Nuimqol robot control|Nuimqol]]/[[Thelodica robot control|Thelodica]]/[[Pelistal robot control]] x 0.01 + [[Target analysis]] x 0.01 ) |
* '''With Weapon Tuning''' : | * '''With Weapon Tuning''' : | ||
− | Damage ( % ) = '''Damage''' x ( 1 + '''% Damage Tuning''' ) | + | Damage ( % ) = '''Damage''' x ( 1 + '''% Damage Tuning''' ) <sup>'''number of tunings'''</sup> |
+ | |||
− | |||
* '''Weapon Cycle Time''' : | * '''Weapon Cycle Time''' : | ||
− | Cycle Time ( s ) = '''Base Cycle Time''' / ( 1 + '''General | + | Cycle Time ( s ) = '''Base Cycle Time''' / ( 1 + '''[[General firing]]/[[Missile launch]]''' x 0.01 + '''[[Rapid-firing]]/[[Complex missile launch]]''' x 0.03 ) / ( 1 + [[Nuimqol robot control|Nuimqol]]/[[Thelodica robot control|Thelodica]]/[[Pelistal robot control]] x 0.01 ) |
* '''With Weapon Tuning''' : | * '''With Weapon Tuning''' : | ||
− | Cycle Time ( s ) = '''Cycle Time''' x ( 1 - '''% Cycle Time Tuning''' ) | + | Cycle Time ( s ) = '''Cycle Time''' x ( 1 - '''% Cycle Time Tuning''' ) <sup>'''number of tunings'''</sup> |
==Mining and Cycle Time == | ==Mining and Cycle Time == | ||
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* '''Mined Amount Increase''' | * '''Mined Amount Increase''' | ||
− | Mining ( % ) = ( '''Basic/Advanced | + | Mining ( % ) = ( '''[[Basic robotics|Basic]]/[[Advanced robotics]]''' x 0.05 + '''[[Extensive mining]]''' x 0.01 + '''[[Industrial robot control]]''' x 0.01 |
− | + '''% Mining Spark''' ) * ( 1 + '''% Extensive Ore Mining''' x 0.03 + '''Extensive Ore Mining''' x 3) | + | + '''% Mining Spark''' ) * ( 1 + '''% Extensive Ore Mining''' x 0.03 + '''Extensive Ore Mining''' x 3) = A |
− | * With Industrial Tuning : | + | |
+ | * '''With Industrial Tuning''' : | ||
Mining( % ) = Previous Mining ( % ) x ( 1 + % Industrial Tuning ) + Industrial Tuning | Mining( % ) = Previous Mining ( % ) x ( 1 + % Industrial Tuning ) + Industrial Tuning | ||
− | + | ||
− | + | Example with all Skill at 10 and Riveler MkII full Tuning => | |
− | Example with all Skill at 10 and | ||
( 10 x 0.05 + 10 x 0.01 + 10 x 0.03 10 x 0.01 ) x ( 1 + 10 x 0.03 ) + 30 = 121 % | ( 10 x 0.05 + 10 x 0.01 + 10 x 0.03 10 x 0.01 ) x ( 1 + 10 x 0.03 ) + 30 = 121 % | ||
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First tuning => 121 x 1.1 +10 = 143.1 % <br /> | First tuning => 121 x 1.1 +10 = 143.1 % <br /> | ||
Second tuning => 143 x 1.1 + 10 = 167.41 % <br /> | Second tuning => 143 x 1.1 + 10 = 167.41 % <br /> | ||
− | Third tuning => 167.41 x 1.1 +10 = 194.151 % <br /> | + | Third tuning => 167.41 x 1.1 + 10 = 194.151 % <br /> |
− | Fourth tuning => | + | Fourth tuning => 94.151 x 1.1 + 10 = 223,5661 % <br /> |
+ | Fifth tuning => 223,5661 x 1.1 +10 = 255.92271 % | ||
+ | |||
+ | Example : A = 121% and 5 T4 industrial tuning (10%) , b =% Industrial Tuning = 0.01 c =Industrial tuning value = 10 | ||
+ | |||
+ | '''[A+(c/b)] x (1 + b )<sup> number of tunings</sup> - (c/b)''' | ||
+ | |||
+ | (121+(10/.1) ) x ( 1 + 0.01 )^5 - ( 10 / 0.1 )= 221x1.1^5 -100 = 255.92271 % | ||
− | |||
* '''Cycle Time Mining''' | * '''Cycle Time Mining''' | ||
− | Cycle Time ( s ) = Base Cycle Time / ( 1 + '''Basic | + | Cycle Time ( s ) = Base Cycle Time / ( 1 + '''[[Basic intensive mining]]''' x 0.01 + '''[[Advanced intensive mining]]''' x 0.02 + '''[[Expert intensive mining]]''' x 0.02+ '''[[Basic robotics|Basic]]/[[Advanced robotics]]''' x 0.05 ) |
* With Industrial Tuning and Fast Extractor [[#Nexus]] module : | * With Industrial Tuning and Fast Extractor [[#Nexus]] module : | ||
− | Cycle Time ( s ) = Cycle Time x ( 1 - '''% Cycle Time Tuning''' ) | + | Cycle Time ( s ) = Cycle Time x ( 1 - '''% Cycle Time Tuning''' )<sup>'''number of tunings'''</sup> x '''% Fast Extractor Module''' |
==Detection and Masking == | ==Detection and Masking == | ||
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* '''Detection :''' | * '''Detection :''' | ||
− | - Signal Detection modification ( % ) = Base Signal Detector x (1 + Signal Detection Skill x 0.02 + Signal Detection Skill x 2 | + | - Signal Detection modification ( % ) = Base Signal Detector x (1 + Signal Detection Skill x 0.02 ) + Signal Detection Skill x 2 |
- Base Bot Signal Detection x % Detection Spark x % Aura Emiter x Signal Detection modification ( % ) | - Base Bot Signal Detection x % Detection Spark x % Aura Emiter x Signal Detection modification ( % ) | ||
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* '''Masking :''' | * '''Masking :''' | ||
− | - Signal Masking modification ( % ) = Base Signal Masking x (1 + Signal Masking Skill x 0.02 + Signal Masking Skill x 2 | + | - Signal Masking modification ( % ) = Base Signal Masking x (1 + Signal Masking Skill x 0.02 ) + Signal Masking Skill x 2 |
- Base Bot Masking Detection x ( 1+ % Spec Ops robot control) x % Masking Spark x % Aura Emiter x Signal Masking modification ( % ) | - Base Bot Masking Detection x ( 1+ % Spec Ops robot control) x % Masking Spark x % Aura Emiter x Signal Masking modification ( % ) | ||
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* '''EW Strengh for ECM and Suppressor with ECM tunings :''' | * '''EW Strengh for ECM and Suppressor with ECM tunings :''' | ||
− | Ew Strengh ( Hw² ) = '''EW Strengh Base''' x ( 1 + | + | Ew Strengh ( Hw² ) = '''EW Strengh Base''' x ( 1 + [[Jamming electronics]] x 0.03 + [[Complex jamming electronics]] x 0.03 + [[Basic robotics|Basic]]/[[Advanced robotics]] x 0.05 ) x ( 1 + '''% ECM Tuning''' )<sup>'''number of tunings'''</sup> |
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* '''Sensor Suppressor locking time :''' | * '''Sensor Suppressor locking time :''' | ||
− | Sensor Supressor locking time base x ( 1 + | + | Sensor Supressor locking time base x ( 1 + [[Sensor suppressing]] x 0.03 + [[Basic robotics|Basic]]/[[Advanced robotics]] x 0.03) + ( [[Sensor suppressing]] + [[Basic robotics|Basic]]/[[Advanced robotics]] ) x 3 |
With Sensor Suppressor Tunings : | With Sensor Suppressor Tunings : | ||
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* '''Sensor Suppressor locking range :''' | * '''Sensor Suppressor locking range :''' | ||
− | Sensor Supressor locking range (%) = 1 - ( % Sensor Supressor locking range base x ( 1 - Basic/ | + | Sensor Supressor locking range (%) = 1 - ( % Sensor Supressor locking range base x ( 1 - [[Basic robotics|Basic]]/[[Advanced robotics]] x 0.02 ) x ( 1 - % Sensor Suppressor Tuning ) ) |
Example with Zenith MKII and T4 Sensor suppressor and T4 Sensor Suppressor Tuning : | Example with Zenith MKII and T4 Sensor suppressor and T4 Sensor Suppressor Tuning : | ||
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* '''Fast Extractor NEXUS :''' | * '''Fast Extractor NEXUS :''' | ||
− | Industrial module cycle time ( % ) = 1 - ( 1 - % Base Industrial module cycle time ) / ( 1 + NEXUS Fast | + | Industrial module cycle time ( % ) = 1 - ( 1 - % Base Industrial module cycle time ) / ( 1 + [[NEXUS - Fast extraction]] x 0.01 ) |
Example with T4 Fact Extractor => 1 - (1 - 0,075) / 1,1 = 15.91 % | Example with T4 Fact Extractor => 1 - (1 - 0,075) / 1,1 = 15.91 % | ||
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* '''Industrial NEXUS :''' | * '''Industrial NEXUS :''' | ||
− | Industrial module accumulator usage ( % ) = 1 - ( 1 - % Base Industrial module accumulator usage ) * ( 1 - NEXUS Industrial | + | Industrial module accumulator usage ( % ) = 1 - ( 1 - % Base Industrial module accumulator usage ) * ( 1 - [[NEXUS - Industrial]] x 0.01 ) |
Example with T4 Fact Extractor => 1 - (1 - 0,075) x ( 1 - 0.1 ) = 16.75 % | Example with T4 Fact Extractor => 1 - (1 - 0,075) x ( 1 - 0.1 ) = 16.75 % | ||
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* '''Navigation NEXUS :''' | * '''Navigation NEXUS :''' | ||
− | * ''' | + | |
+ | * '''Electronic Warfare NEXUS :''' | ||
+ | |||
+ | EW module optimal range (%) = % Base EW module optimal range x ( 1 + [[NEXUS - Electronic warfare]] x 0.02 ) + [[NEXUS - Electronic warfare]] x 2 | ||
+ | |||
+ | Example with T4 Electronic Warfare NEXUS => 7.5 % x 1.2 + 20 = 29 % | ||
* '''Assault NEXUS :''' | * '''Assault NEXUS :''' | ||
+ | |||
+ | ==Production== | ||
+ | |||
+ | Base build time is 800 seconds for ammo, 2000/4000/8000 seconds for modules, 12000 seconds for light robots, 16000 seconds for assault robots, 32000 seconds for mechs and 40000 seconds for heavy mechs. Multiply these values with time efficiency and round down to get the time used. | ||
+ | |||
+ | To get the amount of material required, multiply the nominal material requirement with material efficiency and round down. | ||
+ | |||
+ | * '''Factory''' | ||
+ | |||
+ | Material efficiency = 1 + (1 / ((Material ratio / 50) + 2)) | ||
+ | |||
+ | Time efficiency = 0.9 + (90 / (Facility time ratio + CT time ratio + 100)) | ||
+ | |||
+ | * '''Prototype facility''' | ||
+ | |||
+ | Material efficiency = 10 x (1 + (1 / ((Material ratio / 50) + 2))) | ||
+ | |||
+ | Time efficiency = 10 x (0.9 + (90 / (Time ratio + 100))) | ||
+ | |||
+ | * '''Reverse engineering''' | ||
+ | |||
+ | Process time (time it takes to reverse engineer the item) = 4000 seconds x Required decoder level x (0.9 + (90 / (Facility time ratio + Bonus time ratio + 100))) | ||
+ | |||
+ | Bonus time ratio is the extra ratio applied for using higher leveled decoders than required. |
Latest revision as of 01:05, 17 February 2014
Contents
Damage and Weapon Cycle Time
- Damage :
Damage ( % ) = Base Damage x ( 1 + Basic/Advanced robotics x 0.05 + Basic/Advanced Weapon ) x ( 1 + Nuimqol/Thelodica/Pelistal robot control x 0.01 + Target analysis x 0.01 )
- With Weapon Tuning :
Damage ( % ) = Damage x ( 1 + % Damage Tuning ) number of tunings
- Weapon Cycle Time :
Cycle Time ( s ) = Base Cycle Time / ( 1 + General firing/Missile launch x 0.01 + Rapid-firing/Complex missile launch x 0.03 ) / ( 1 + Nuimqol/Thelodica/Pelistal robot control x 0.01 )
- With Weapon Tuning :
Cycle Time ( s ) = Cycle Time x ( 1 - % Cycle Time Tuning ) number of tunings
Mining and Cycle Time
- Mined Amount Increase
Mining ( % ) = ( Basic/Advanced robotics x 0.05 + Extensive mining x 0.01 + Industrial robot control x 0.01 + % Mining Spark ) * ( 1 + % Extensive Ore Mining x 0.03 + Extensive Ore Mining x 3) = A
- With Industrial Tuning :
Mining( % ) = Previous Mining ( % ) x ( 1 + % Industrial Tuning ) + Industrial Tuning
Example with all Skill at 10 and Riveler MkII full Tuning =>
( 10 x 0.05 + 10 x 0.01 + 10 x 0.03 10 x 0.01 ) x ( 1 + 10 x 0.03 ) + 30 = 121 %
First tuning => 121 x 1.1 +10 = 143.1 %
Second tuning => 143 x 1.1 + 10 = 167.41 %
Third tuning => 167.41 x 1.1 + 10 = 194.151 %
Fourth tuning => 94.151 x 1.1 + 10 = 223,5661 %
Fifth tuning => 223,5661 x 1.1 +10 = 255.92271 %
Example : A = 121% and 5 T4 industrial tuning (10%) , b =% Industrial Tuning = 0.01 c =Industrial tuning value = 10
[A+(c/b)] x (1 + b ) number of tunings - (c/b)
(121+(10/.1) ) x ( 1 + 0.01 )^5 - ( 10 / 0.1 )= 221x1.1^5 -100 = 255.92271 %
- Cycle Time Mining
Cycle Time ( s ) = Base Cycle Time / ( 1 + Basic intensive mining x 0.01 + Advanced intensive mining x 0.02 + Expert intensive mining x 0.02+ Basic/Advanced robotics x 0.05 )
- With Industrial Tuning and Fast Extractor #Nexus module :
Cycle Time ( s ) = Cycle Time x ( 1 - % Cycle Time Tuning )number of tunings x % Fast Extractor Module
Detection and Masking
- Detection :
- Signal Detection modification ( % ) = Base Signal Detector x (1 + Signal Detection Skill x 0.02 ) + Signal Detection Skill x 2
- Base Bot Signal Detection x % Detection Spark x % Aura Emiter x Signal Detection modification ( % )
- Masking :
- Signal Masking modification ( % ) = Base Signal Masking x (1 + Signal Masking Skill x 0.02 ) + Signal Masking Skill x 2
- Base Bot Masking Detection x ( 1+ % Spec Ops robot control) x % Masking Spark x % Aura Emiter x Signal Masking modification ( % )
ECM and Suppressor
- EW Strengh for ECM and Suppressor with ECM tunings :
Ew Strengh ( Hw² ) = EW Strengh Base x ( 1 + Jamming electronics x 0.03 + Complex jamming electronics x 0.03 + Basic/Advanced robotics x 0.05 ) x ( 1 + % ECM Tuning )number of tunings
- Sensor Suppressor locking time :
Sensor Supressor locking time base x ( 1 + Sensor suppressing x 0.03 + Basic/Advanced robotics x 0.03) + ( Sensor suppressing + Basic/Advanced robotics ) x 3
With Sensor Suppressor Tunings :
Sensor Supressor locking time x ( 1 + % Sensor Suppressor tuning ) + Sensor Suppressor tuning
Example with Skill at 10 and T4 Sensor suppressor and T4 Sensor suppressor tuning :
40 x ( 1 + 0.6 ) + 60 = 124 % => 124 x 1.17 + 17 = 162.08 % locking time
- Sensor Suppressor locking range :
Sensor Supressor locking range (%) = 1 - ( % Sensor Supressor locking range base x ( 1 - Basic/Advanced robotics x 0.02 ) x ( 1 - % Sensor Suppressor Tuning ) )
Example with Zenith MKII and T4 Sensor suppressor and T4 Sensor Suppressor Tuning :
1 - ( 1-0.25 )*( 1- 10 x 0.02) x ( 1 - 0.1 ) = 46 % locking range
Nexus
- Fast Extractor NEXUS :
Industrial module cycle time ( % ) = 1 - ( 1 - % Base Industrial module cycle time ) / ( 1 + NEXUS - Fast extraction x 0.01 )
Example with T4 Fact Extractor => 1 - (1 - 0,075) / 1,1 = 15.91 %
- Industrial NEXUS :
Industrial module accumulator usage ( % ) = 1 - ( 1 - % Base Industrial module accumulator usage ) * ( 1 - NEXUS - Industrial x 0.01 )
Example with T4 Fact Extractor => 1 - (1 - 0,075) x ( 1 - 0.1 ) = 16.75 %
- Navigation NEXUS :
- Electronic Warfare NEXUS :
EW module optimal range (%) = % Base EW module optimal range x ( 1 + NEXUS - Electronic warfare x 0.02 ) + NEXUS - Electronic warfare x 2
Example with T4 Electronic Warfare NEXUS => 7.5 % x 1.2 + 20 = 29 %
- Assault NEXUS :
Production
Base build time is 800 seconds for ammo, 2000/4000/8000 seconds for modules, 12000 seconds for light robots, 16000 seconds for assault robots, 32000 seconds for mechs and 40000 seconds for heavy mechs. Multiply these values with time efficiency and round down to get the time used.
To get the amount of material required, multiply the nominal material requirement with material efficiency and round down.
- Factory
Material efficiency = 1 + (1 / ((Material ratio / 50) + 2))
Time efficiency = 0.9 + (90 / (Facility time ratio + CT time ratio + 100))
- Prototype facility
Material efficiency = 10 x (1 + (1 / ((Material ratio / 50) + 2)))
Time efficiency = 10 x (0.9 + (90 / (Time ratio + 100)))
- Reverse engineering
Process time (time it takes to reverse engineer the item) = 4000 seconds x Required decoder level x (0.9 + (90 / (Facility time ratio + Bonus time ratio + 100)))
Bonus time ratio is the extra ratio applied for using higher leveled decoders than required.