Tutorial:Circuit network cookbook: Difference between revisions

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* Since items should only be released if the belt starts to clear, the counter (D) is evaluated by the belt (E) which is only activated, if item-count on (D) is smaller than 6 (this number has to be adjusted to personal needs, when the cache should become "active" and release items)
* Since items should only be released if the belt starts to clear, the counter (D) is evaluated by the belt (E) which is only activated, if item-count on (D) is smaller than 6 (this number has to be adjusted to personal needs, when the cache should become "active" and release items)
* The layout can be extended to cache whatever amount of items is required. (Some balancing for the release-method would be required ofc.)
* The layout can be extended to cache whatever amount of items is required. (Some balancing for the release-method would be required ofc.)
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[[File:combinatorMultiplierDetailed.png|left|400x400px]]
=== Multiplier and Dictionaries/Arrays ===
* Multiplying two signals together is simple and requires only a single combinator, however multiplying a set of signals is more complicated.
* A proof is shown below for the equation and why it works.
* A dictionary is a system that allows a value on a specific signal to be accessed. For example, A can contain many signals (either from a constant combinator or memory cell) and B can contain 1 of a specific signal (such as blue signal). What remains is the blue-signal value from A. This is because all the other signals are multiplied by 0.
* Arrays are similar to dictionaries, but instead of using a signal as a key, we use a number. Constant combinators are placed mapping each signal to a unique number (such as 1 yellow belt, 2 red belt, 3 blue belt, 4 burner inserter, etc). Then, use a combinator of "each = index OUTPUT 1 of each" and plug that in as the input to a dictionary.
[[File:combinatorMultiplierMath.png|left|400x400px]]
    ((A+B)^2 - (A-B)^2)/4 = AB
    (A+B)^2 - (A-B)^2 = 4AB
    (A^2 + 2AB + B^2) - (A^2 - 2AB + B^2) = 4AB
    4AB = 4AB


{{clear}}
{{clear}}

Revision as of 01:09, 17 May 2017

Foreword

This page provides examples of simple circuit network designs and some not so simple designs that others can use, combine and modify. They are designed to be as easy to understand as possible. To see the settings of combinators without opening them, the option "Show combinator settings when detailed info is on" in the graphics options has to be checked and detailed info has to be turned on.

Oil Setups

LgtOilCracking.png

Light Oil Cracking

  • This circuit provides balanced light oil and petroleum gas production by cracking excess light oil into gas.
  • The Small pump is connected to the Storage tank by a Red wire.
  • The small pump has an enabled condition set to Light Oil > 2000.
HvyOilCracking.png

Heavy Oil Cracking

  • This circuit extends on the previous circuit by adding optional heavy oil cracking to provide lubricant etc.
  • The Small pump has an enabled condition set to Heavy oil > 2000.
BalancedPlasticSulfur.png

Petroleum split evenly between plastic and sulphuric acid

  • This circuit buffers gas in the tank until there is at least 100, then it lets the tank drain until there is less than 50 and the cycle repeats.
  • It has a few elements that work together to do achieve this.
  • Firstly the Small pump is connected to the Wooden chest by a Red wire and the enabled condition on the Small pump is set to Raw wood > 0.
  • Both of the Basic inserters are connected to the Storage tank by Red wires.
  • The enabled condition on the left inserter is Petroleum gas > 100
  • The enabled condition on the right inserter is Petroleum gas < 50.
  • You will need to insert a single "Raw wood" into the chest to make it all work.


  • It is also possible to do this with decider combinators instead of the inserters, belt and the Wood chest or even just belts.

Lights

ConditionalLights.png

Conditional Lights

  • In this circuit we connect a series of lamps to a Storage Tank.
  • By setting different conditions on each lamp we can build an indicator strip.
  • The Enabled condition of the first lamp is Petroleum gas > 100.
  • The others light up when gas is greater than 200, 300, 400 and 500 respectively.

In this scenario you can connect the storage tank to the lamps directly.


ColoredLights.png

Colored Lights

  • To light a lamp with a color rather than white, you need an intermediate device like an Arithmetic combinator that can send a color signal.

Instead of directly connect the the Lamp and the Storage tank you need:
1 Add the Arithmetic combinator.
2 Connect the Storage tank with the input of the Arithmetic combinator.
3 Connect the output of the Arithmetic combinator with the lamp.
4 Set up the Arithmetic combinator:
4.1 Setting the input to Petroleum Gas + 0 (the constant 0 not the signal 0)
4.2 Set the output to the Pink signal (on the bottom row of the last tab of signals.)
5 Set up the lamp:
5.1 Select the "Use colors" check box on the lamp.
5.2 Set the condition to the Pink signal, and what value you want (i.e. > 100)

Misc

MulitipleChestsAndPoles.png

Multiple Storages

  • If you connect multiple chests to a pole, the pole displays the sum of items in all the chests.
  • This also works with Storage tanks and roboports.
ConstantComb.png

Constant combinator

  • With a constant combinator you can generate any signals you may need.
  • In this example we have generated a signal of 50 Laser turrets and 200 Piercing round magazine.
  • Constant combinators are not of much use on their own but we shall use them later.
LogicGates.png

Logic gates

  • In each case the two inputs can be connected with the same color wire or different colors. The inputs are powered by two Constant combinators each of them output an A signal with value 1 for true and nothing or false.
  • You can use Decider combinators to make all of the common logic gates.
  • The output for each should be set to 1 and the signal of your choice.
  • Use the following settings to create different gates:
   NOT  A=0
   NOR  A=0
   NAND A<2
   XOR  A=1
   AND  A=2
   OR   A>0
ThisASign.png

Constant combinator signs

  • You can use Constant combinators to make signs, just set the letter signals in the combinator, each combinator can display 2 characters side by side.
MemoryCell.png

Memory Cell / Counter

  • Basic memory cell that counts all the items moved by the inserter
  • The Fast inserter is connected to BOTH ends of the arithmetic combinator.
  • If the Fast inserter hasn't picked anything up this tick the input to the Arithmetic combinator is the same as and output and hence the values are persisted.
  • When the Fast inserter does pick something up its value is added to the output from the previous tick thus incrementing that item.


BeltCache.png

Automatic Belt-Cache

  • Some intermediate products are huge in demand during peak-production only. To bypass the need of providing a huge amount of factories in order to cover that peaks, a cache-unit can be used. The unit stores items, while the belt has backed up (so theres obviously no current demand downstream) and releases items as soon as the belt gets too empty.
  • The blue area are 3 parts of Express belts. According to the wiki, each belt can hold up to 7.11 items. This means the feeding fast belt can not provide 7.11 items for the express belts as long as the belt is moving. (And while the belt is moving, we don't want to cache items, but let regular production run, or even release items from the cache.)
  • This means, once the counters on the two express belts are 7.11 each, the belt has backed up, so we can start "caching" items into our storage array.
  • For this purpose, the counters are connected to the arithmetic combinator (A) which multiples the input (*100) into green signals. So, if the belt has backed up, B shows ">1422" green signals.
  • This is the activation condition for the Belt (C), which will redirect the input tp the storage array.
  • Since items should only be released if the belt starts to clear, the counter (D) is evaluated by the belt (E) which is only activated, if item-count on (D) is smaller than 6 (this number has to be adjusted to personal needs, when the cache should become "active" and release items)
  • The layout can be extended to cache whatever amount of items is required. (Some balancing for the release-method would be required ofc.)


CombinatorMultiplierDetailed.png

Multiplier and Dictionaries/Arrays

  • Multiplying two signals together is simple and requires only a single combinator, however multiplying a set of signals is more complicated.
  • A proof is shown below for the equation and why it works.
  • A dictionary is a system that allows a value on a specific signal to be accessed. For example, A can contain many signals (either from a constant combinator or memory cell) and B can contain 1 of a specific signal (such as blue signal). What remains is the blue-signal value from A. This is because all the other signals are multiplied by 0.
  • Arrays are similar to dictionaries, but instead of using a signal as a key, we use a number. Constant combinators are placed mapping each signal to a unique number (such as 1 yellow belt, 2 red belt, 3 blue belt, 4 burner inserter, etc). Then, use a combinator of "each = index OUTPUT 1 of each" and plug that in as the input to a dictionary.
CombinatorMultiplierMath.png
   ((A+B)^2 - (A-B)^2)/4 = AB
   (A+B)^2 - (A-B)^2 = 4AB
   (A^2 + 2AB + B^2) - (A^2 - 2AB + B^2) = 4AB
   4AB = 4AB

Inserters

LimitItemsPlacedIntoAChest.png

Limit items placed into a chest

  • The Basic inserter is connected to the Wooden chest using a Red wire.
  • The inserter's enabled condition is Advanced Circuit < 10.
  • In reality this means the inserter may place more than 10 Advanced circuits in the chest because it could pick up-to 3 at once.
  • This effect can be even greater with Stack inserters because of their large carrying capacity.
  • This technique still gives far greater control than limiting the inventory on the chest.
SmartOutpostUnloader.png

Keeping outpost stocked with specified items


  • So the input to the stack filter inserter is <Constant combinator> - <Storage chest contents> and the filter is set to filter the item of greatest demand.


SolarAccumalatorBalancer.png

Balanced Solar panel / Accumulator Production

  • This circuit balances production of Solar panels and Accumulators to a desired ratio in my case 24:20.
  • The first Arithmetic combinator takes the number of accumulators in the chest and multiples it by 24.
  • The second Arithmetic combinator takes the output of the first combinator and divides it by 20.
  • This gives us the number of accumulators that we can directly compare to the number of Solar panels in both inserters.
  • If the number of accumulators is greater we enable the Solar panels inserter, if the number of Solar panels is greater we enable the accumulators inserter.
  • However, if they are equal, neither machine does anything. So we add a single accumulator to one of the inserters using a constant combinator and a wire of the other color, therefore breaking the deadlock.

Sushi Belts

SushiScience1.png

Reading Belt Design

  • Six belts in a row are connected with Red wire and set to Read belts contents and Hold
  • This Red wire is then connected to the inserters that insert onto the belt.
  • Read hand contents is unselected for all inserters.
  • Mode of operation is set to Enable/Disable on all inserters.
  • The first inserter is enabled when Science pack 1 = 0
  • The other inserters are set similarly for the other science packs.

left]

Memory Cell Design

  • This circuit counts the number of items of each type on a looping belt by counting the numbers that are added and removed from the belt by inserters.
  • Each inserter that takes items off the belt is connected together with Red wire and each of these inserters is set to Mode of operation none, Read hand content selected and Hand read mode pulse.
  • These inserters are connected to the input of the left arithmetic combinator.
  • The left Arithmetic combinator multiples each input by -1 and outputs it to each.
  • The right Arithmetic combinator is a memory cell as above.
  • The memory cell's input is connected to the inserters that are placing items on the belt and the output of the left Arithmetic combinator.
  • The inserters that place items onto the belt have an enabled condition that is based on the number of items on the belt.

Splitters

CondSplitter.png

Conditional splitter

  • This is the most simple circuit you can have for "controlling" a splitter.
  • A signal X=1 is transmitted from off screen when the items need to be sent down the belt.
  • The belt on the left is enabled when X=1.
  • The belt on the right is enabled when X=0.
  • The two belts are wired together and to a pole.
PrioritySplitter.png

Priority Splitter

  • This circuit prioritizes items to the belt going of the screen to the left but will send items straight on if the belt to the left is backed up.
  • Its not perfect and will leak some items but its good enough for most applications.
  • The balancer means it will work even if the supply or demand is uneven.


  • It is critical that the belts are setup as in this picture otherwise it may not work.

Power

SteamBackup.png

Backup steam power

Latches

SRLatch.png

SR latch

  • This should be familiar to anyone with any background in electronics.
  • The signal is set and reset with the constant combinators on the left by setting an A=1 signal.
  • The latch "remembers" which one was last set and the light stays on until another signal is received.
SRlatchinaction.png

Usage of SR latch

  • Here is an example of how you could use an SR latch.
  • The two extra Decider combinators provide the set and reset conditions.
  • Petroleum gas < 50 and petroleum gas > 100.
BeltLatch.png

Belt only latch

  • This is the most compact latch I am aware of.
  • To make it work you need to place 3 raw wood on the inside lane of the belt.
  • I believe it will have higher latency than the combinator version but in most situations you will not notice the difference.

Displays

5digitDisplay.png

Numerical Display

  • Each digit is driven by its own Green wire, that wire holds 15 signals one for each lamp used in the digit.
  • Constant combinators are used to define which lamp should light up for each value.
  • Blueprint string including decoder [1]
BWDisplay.png

Black and White Grid Display

  • Each row has its own Red wire connection and within that row each light has a numbered signal 0-9.
  • We turn each light on by just setting or clearing the relevant signal.
MultiColoredDisplay.png

Multicolor Display by DaveMcW

  • To understand how this works, you first need to understand how color lights choose which color to light up when there are multiple colored signals.
  • The lamp will light up with the colored signal that is greater than zero and earliest in this list: Red, Green, Blue, Yellow, Pink, Cyan, White.
  • We have a Red wire per column, that wire has each of the colored signals on it at different values and a numbered signal for each row.
  • There is a Arithmetic combinator for each cell that subtracts the "row" value from each of the colored signals.
  • And this enables us to choose the color for each cell.
  • Simple!

See Also