Участник:Semorerith

Шаблон:Gameplay Guides Эта инструкция описывает использование Принтера интегральных схем, универсального устройства, с помощью которого можно создавать особые предметы, которые называются сборками. Сборки имеют широкий набор возможностей, которые ограничиваются только воображением игрока и размером корпуса. Можно создавать специализированные сигнализаторы, интеллектуальные аугментации, взрывчатку, раздатчики лекарств и химических веществ, передвижных механических помощников и многое другое. В конце инструкции есть некоторые примеры таких устройств.

Creating a new integrated circuit can take some time, and for the more complex types requires a basic knowledge of how logic works in boolean algebra. However they can be easily copied and brought into future rounds. It can represent an interesting puzzle to implement your desired functions within the, quite restrictive, limits of the assembly sizes.

Assemblies can be extremely powerful, make sure to be creative and have fun making your circuits, but remember the rules and don't stray into powergaming or griefing with circuits.

Tools

• Producing integrated circuits all starts with an integrated circuit printer. This item is found in the research and robotics labs, or produced from a protolathe. Interacting with it opens a UI that allows you to print all the parts required for the creation of integrated circuits, and the tools for attaching them together. It also allows for cloning of circuits. The printer uses steel sheets and can recycle unwanted circuits and components.
• The integrated circuit printer initially has many options crossed-out. These are more advanced components and must be unlocked by using an 'integrated circuit printer upgrade disk - advanced designs' on the printer. This disk is printable from the protolathe with sufficient research.
• Cloning circuits can take minutes for the more complex varieties. The 'integrated circuit printer upgrade disk - instant cloner' allows for instantaneous cloning of integrated circuits. It is printed from a protolathe with sufficient research.
• Interacting with an opened assembly casing using the circuit wirer allows you to connect the various components within together, and is essential to creating integrated circuits. This can be found in the research and robotics labs, or printed from the integrated circuit printer. Pressing Шаблон:Kp toggles the wirer/unwirer mode and removes the previously selected pin.
• The circuit debugger can save you a great deal of time when creating integrated circuits. Interacting with it allows you to set an input number, string, reference or null and then set this on the input of a component. This is useful in setting constants and testing the operation of your circuit. It is found in the same places as the circuit wirer.
• The circuit detailer allows you to adjust the colour of your assembly casing. It is found in the same places as the circuit wirer.
• The circuit analyzer allows you to obtain a set of instructions for the integrated circuit printer that will allow you to clone your circuit by using the Load Program button in the printer UI. This text can be saved externally for use in future rounds. You can use the analyzer on circuits other people have created. Adjusting this text is sometimes simpler than editing the circuit directly with a circuit wirer.

Assemblies

There are many types of assemblies, which act as containers for your integrated circuits. Assemblies each have a space (physical internal volume) and a complexity (a cap on the amount of complicated circuits you can include) and some additional features based on the shape of the assembly, (e.g. The one that resembles a PDA can have an ID Card inserted.)

Assemblies fit into four main categories: Assembly, Mechanism, Machine and Drone.

Assembly-class Assemblies are the smallest in space and complexity, but have some features based on their small size. Such as the ability to fit in belt or PDA slots, or inside an augment.

Mechanism-class Assemblies are larger, but cannot fit so easily on your character. They are more suited for assemblies that could sit on a table and perform their function. They have twice the space and complexity of the Assembly-class.

Machine-class Assemblies are the largest and can be affixed to the floor and treated like a piece of furniature. These allow you to build the most complicated integrated circuits. They have four times the space and complexity of the Assembly-class.

Drone-class Assemblies allow you to create robots that can move and interact with the world. They have three times the space and complexity of the Assembly-class.

Additionally, there are two wall-mounted assemblies, which resemble screens that can be attached to a wall. They have twice the space and complexity of the Assembly-class.

As assemblies get larger they also take more steel to create from the printer.

Below is a table that lists each assembly and what special features it has.

Components

There are many categories of component, below they will be listed along with a brief description of what you can expect from each category.

Circuit Design

Once you have decided on your assembly type, and what you want your circuit to do - It is time to print all the components and insert them into your assembly. Once this is done, use the Circuit Wirer on the open assembly casing to open the assembly internals screen.

Assembly Internals Screen

In-game UI showing an integrated circuit components screen.

On this screen you will see a list of the current complexity and space, and their maximum, the power cell status, as well as a list of the installed components.

Component Screen

Clicking on any component will bring up that component's settings, wiring and a description of what it does. In this screen you can also rename, copy the reference of or remove that component.

In-game UI showing the Advanced Medical Scanner Circuit

Here we have an example of one of the medical scanner components, which when used on a target will give the assembly information on its health.

On the left side of the screen we see <REF> target (null) - This means we need to provide the circuit with a target reference as an input. Currently we have null or nothing input. Using another component such as a sensor and wiring it to the medical scanner circuit, we can provide it with a reference. Variables are always written in the format <Type> name (current). Types can be Any, REF, String, NUM or BOOL - And you can only connect compatible pins together. If you wish to send the output of a NUM pin to, for example, a screen for display - Then you will have to pass it through a num to string component first to change the type.

In the center we have the pulse pins, these tell the circuit when to trigger and where to send out a pulse when it operates. We might wire the scan pin to a sensor output trigger, so that when we have scanned something and we know that the reference will be passed to the medical scanner, we tell the medical scanner to operate using that reference. Then we could use the output of the medical scanner to trigger another component such as a screen to display the scan.

Connecting Components

Connect the components using the Circuit Wirer. It has two modes, Wire and Unwire, which can be toggled with Z or by clicking on the Wirer. To wire or unwire, click on the two pins you wish to wire/unwire. They must be compatible, i.e. You cannot wire a pulse pin to a variable pin, nor can you connect pins with incompatible types. Pins can have multiple connections.

Example of a connected circuit, this modulus circuit forms part of a looping counter circuit in a medical scanner assembly. It allows the assembly to cycle through all the damage types on a loop.

Occasionally, you will not want to connect a pin to anything - But you will still want it to have a variable. This may be the case with a ticker that you always want to be on, so it requires a <BOOL> True on the input. You can achieve this using the Circuit Debugger. Double-click the Debugger in-hand to open a menu to allow you to select a variable type, select the variable you want and then input the value. Then click on the appropriate pin with the debugger to set the value. An example of this can be seen in the above image, in which pin <NUM> B is permanently set to 7. The debugger can also be used to pulse a trigger pin to allow you to test out your circuit.

Sample Circuits