Difference between revisions of "Capacitor warfare"

Weapon Systems
Turrets
Turret mechanics
Missiles
Missile mechanics Fitting missile launchers
Drones
Drone mechanics Drone Capable Ships Fighters
Other Weapon Systems
Smartbombs Bombs Guided Bombs Vorton Projectors
Other Mechanics
Overheating Electronic warfare Capacitor warfare

Visual effects for Energy Neutralizers (left) and Energy Nosferatus (right)

Capacitor warfare is the attack strategy of using equipment to drain a target ship's capacitor, its available energy for powered modules. A ship without sufficient capacitor energy can lose the ability to fire certain weapons, actively repair itself, use propulsion equipment or other powered modules, or even warp to another location.

Overview

Heavy Energy Neutralizer I stats

Capacitor warfare (or "cap warfare") equipment drains capacitor energy from the target ship. Both modules and drones are available and come in multiple types:

• Energy Neutralziers ("neuts") destroy capacitor energy, consuming a large amount from the attacker to nullify a similar amount from the target ship. [High slot, short range]
• Energy Nosferatu ("vampires", "NOS") siphon a small amount of energy, transferring it from the target to the attacker (with restrictions). [High slot, short range]
• Energy Neutralizer Drones - Light, medium, and heavy drones, and a wing of support fighters, based on Amarr combat drones.

Cap warfare modules are fitted into a ship's High slot, and both types, Neutralizers and Nosferatu, operate at short range. (By contrast, most electronic warfare modules are Mid slot modules and operate at mid-range or long-range.) While conventional weapons require a turret or missile launcher High slot, a capacitor warfare module has no such requirement and can fit into any High slot.

Ships can resist capacitor warfare by fitting modules with Neutralizer Resistance, such as the Cap Battery. Also, one ship may transfer capacitor energy to another by using a Remote Capacitor Transmitter.

Limitations

Some systems are unaffected by capacitor warfare. Projectile turrets and Missile Launchers do not require capacitor energy to operate. Shields continue to function and regenerate without capacitor needs, and subspace engines still function. However, a ship with a fully drained capacitor cannot warp or activate propulsion equipment, severely limiting range control and escape options.

General principles

Understanding capacitor warfare requires an understanding of capacitor mechanics. Capacitors are a self-recharging resource measured in gigajoules (GJ), with a capacitor recharge rate determined both by the specific ship and the percentage level of the capacitor, measured in gigajoules per second (GJ/sec). The 'peak' recharge rate occurs at 25% capacity, with the recharge rate sharply decreasing below this amount, and more gradually decreasing above it. Therefore, the rate of recharge is lowest when the capacitor is full (100%) or empty (0%). This is the same principle that governs the recharge rate of shields, though the values are slightly different.

The goal of capacitor warfare is to use enough neutralization to overcome the peak recharge rate of the target's capacitor, and while capacitors recharge continuously over time, Neutralizers remove capacitor in single large chunks with every module cycle. As a result, the effectiveness of Neutralizers is often expressed in effective GJ/sec to facilitate easier comparison to the target's recharge rate. Capacitor warfare will have the smallest relative effects at around peak recharge, as the amount of capacitor removed will be countered by the highest recharge rate the target's capacitor is capable of. As a result, it is much more difficult to "break" a target by bringing its capacitor below 25% than it is to keep it at 0% once it gets there. (i.e. it may take 3 Neutralizer modules to bring a target below 25%, but only one Neutralizer module to keep it at close to 0.) As such, the common rule of thumb for Neutralizer-focused ships or fleets is to have much higher neutralization potential than the enemy's conceivable recharge rate.

This being said, even without sufficient neutralizers to break a target, neutralizers can still have a meaningful effect on them. A pilot whose ship is hovering at around 30% capacitor needs to start making choices about which capacitor-consuming modules to use or not use, or may need to start using a Cap Booster to keep themselves up. Being forced to choose which modules not to run opens room for mistakes, and may force the target pilot to choose between not performing their role in the fleet, or dying; and Cap Booster charges will eventually run out in a longer fight and result in a slow death by attrition.

Like many other Electronic Warfare modules, Capacitor Warfare modules have both Optimal and Falloff ranges. Using modules outside their Optimal range results in reduced effectiveness. The formula for effectiveness loss is the same as Turret falloff:

• at 100% Optimal + 0% Falloff = 100% Effectiveness
• at 100% Optimal + 100% Falloff = ~50% Effectiveness
• at 100% Optimal + 200% Falloff = ~6% Effectiveness
• at 100% Optimal + 300% Falloff, the module shuts down as the target is considered 'out of range'.

Like weapons, capacitor warfare modules benefit from overheating; as an overheated weapon deals more damage-per-second, an overheated capacitor warfare module sucks the opponent dry faster.

Energy Neutralizers

Energy Neutralizers ("Neuts", also formerly called Energy Destabilizers) are the heavy hitters of capacitor warfare, able to remove large amounts of capacitor and leave an enemy capped out faster than any other capacitor warfare system. However, they also require a large amount of capacitor to activate and have a long cycle time. Energy Neutralizers have relatively short ranges, though this range scales with module size to retain effectiveness on larger hulls.

All neutralizers have a similar set of attributes. The different sizes of neutralizer differ significantly, but for each size tier they are fairly consistent across meta levels. Aside from fitting considerations, the only attributes that change from meta 0 all the way to commander modules is the range and the amount of energy neutralized.

• Module activation cost is consistent (45 GJ for small, 150 GJ for medium, and 500 GJ for heavy). Therefore, at each size, higher meta modules are more efficient: meta 0 modules destabilize as much as their activation cost (100% efficiency), and this efficiency trends up to meta 5 (tech II) and higher modules at 120% efficiency. Module activation costs are reduced by the  Capacitor Emission Systems skill, which provides 33% increased efficiency at level V.
• Cycle time is also consistent (6 seconds for small neuts, 12 seconds for medium, and 24 seconds seconds for heavy).
• Optimal range for modules from meta 0 to the highest are: small from 4,000m - 9,000m; medium from 8,000m - 16,500m; heavy from 16,000m - 32,000m; and capital from 30,000m - 40,000m.
• Faction and Deadspace Neutralizers have increased range, but the same drain amount as T2 variants. Faction Neutralizers have reduced CPU and Powergrid costs; Deadspace Neutralizers have increased Powergrid costs.
• Overheating a neutralizer shortens its cycle time, which means it will drain its target's capacitor faster but (users should remember) also that it will put an increased load on its user's capacitor.

When activating an Energy Neutralizer on a target, the activation cost will immediately be deducted from the neutralizer's capacitor and the neutralization amount (modified, if in falloff range or if the target has some form of resistance) will be immediately deducted from the target's capacitor. This will be repeated each cycle time for as long as the neut is activated.

Energy Nosferatu

'Energy Nosferatu (also called "NOS" or "Energy Vampires") remove small amounts of capacitor from their target and use it to recharge the user's capacitor, and cycle more quickly than Energy Neutralizers. However, Energy Nosferatu are far more restricted in their effectiveness due to the double upside inherent in their use. Energy Nosferatu share the limited range of Energy Neutralizers, and drain much less capacitor. Most importantly, Energy Nosferatu only transfer capacitor when the user's capacitor is less than the target's capacitor. This is measured in terms of absolute capacitor amount, not capacitor percentage, e.g. a capacitor with 120 GJ of capacitor will always be able to transfer capacitor from a ship with 2000 GJ, regardless of what percentage of each ship's capacitor those amounts represent.

Blood Raider ships have a unique interaction with Energy Nosferatus: Nosferatus used by Blood Raider ships ignore the target's capacitor level, and always transfer energy. This means that, for a Blood Raider ship, a Nosferatu is functionally both an indefinitely sustainable Neutralizer with a lower strength but a much shorter cycle time, and a Cap Booster that does not consume cap charges. This also means that a Blood Raider-run Nosferatu can be used to test whether or not a target ship's capacitor is dry: that NOS will only start draining 0GJ/cycle if the target has 0GJ available.

All Nosferatus have a similar set of attributes. The different sizes of Nosteratus differ significantly, but for each size tier they are fairly consistent across meta levels. Aside from fitting consideration, the only attributes that change from meta 0 all the way to commander modules is the range and the amount of energy transferred to the user.

• Cycle time is consistent (2.5 seconds for small NOS, 5 seconds for medium, and 10 seconds for heavy).
• Small Nosferatu will transfer from 8 - 10 GJ across the meta levels, medium from 30 - 36 GJ, and heavy from 100 - 120 GJ.
• Optimal ranges for all the modules from meta 0 to the highest are between: small from 4,000m - 9,000m; medium from 8,000m - 16,500m; and heavy from 16,000m - 32,000m.
• As with neutralizers, overheating a Nosferatu module decreases its cycle time. Unlike overheating a neutralizer, this will result in both more energy drained from the target's capacitor, and more energy deposited in the user's capacitor.