Tutorials/Minecarts

This tutorial covers basic minecart stations and systems and is designed for those without significant redstone knowledge and only minor experience with minecarts and rails. This tutorial doesn't touch on furnace or storage minecarts. Images below do not always show a space-saving design, but rather one that makes all components immediately visible.

Minecarts
The following are the most important properties of minecarts.
 * Minecarts move at 8 m/s at top speed on a straight track. On a diagonal track they move at 11.314 m/s = sqrt(2) * 8.
 * Minecarts move differently depending on their load.
 * A minecart with a player inside travels 221m from full speed.
 * A fully loaded hopper or chest minecart travels 40m from full speed.
 * An empty hopper or chest minecart travels 165m from full speed.
 * A chest minecart carrying 320 items (5 stacks) travels 101m from full speed.
 * Activated powered rails, down slopes, and being pushed by players or mobs add momentum to a cart, increasing its speed.
 * A player riding in a cart may add momentum by "pushing" it using the "move forward" control, which is set at the key by default.
 * A stretch of an unactivated powered rail of at least two blocks length brings a loaded cart at full speed to a complete halt.
 * A long stretch of rail or an up-slope reduces a cart's momentum and thus its speed, eventually stopping it unless the forward key is held throughout by a player riding the cart.
 * Minecarts "bounce" off of obstructions on the track. Running into a player, mob, or a stopped cart causes it to reverse direction, even on a powered track.

Rails
Please see the individual pages for each type of rail for information on their properties and basic usage:
 * Rails always have to sit on another solid block and are the only rail type that can curve.
 * Detector rails give off a redstone signal when a cart passes over them, otherwise they act as a regular rail.
 * Powered rails add momentum to a cart passing over them when powered, when unpowered they have a braking action and slow or even stop a cart.
 * Activator rails trigger an action on a cart passing above them when powered: TNT minecarts are set off, a hopper cart gets deactivated, and players/mobs riding in one are pushed out of it.

The rest of this page discusses the use of these components in building tracks and rail transport systems.

Best practices for laying tracks
The performance of a rail line is affected by the way the track is placed. Running track next to a wall (see below) or having hills to climb adversely affect the speed of a cart, and so its distance traveled.

Some YouTube videos suggested that diagonal track might offer better performance than straight runs, this has not been proven to be the case. Another distance trial track was constructed with a length of 300 blocks. Carts with no rider travel the same distance as on the straight track, about 18 blocks before they stop, and a cart with a player riding can make it to the end of the track. The interaction with blocks next to the track seems to be a little stronger with carts on a diagonal track. With lampposts placed only every 10 blocks along the track an unmanned cart could cover only 12 blocks, and with a player riding just over 180 blocks, a significant reduction.

What the tests have confirmed is the increase in speed. On each curved track, a cart effectively moves 2 blocks, thus its maximum speed is 11.314 m/s, an improvement over the maximum of 8 m/s on a straight track.

A minecart with no rider, at full speed, can climb 10 blocks on unpowered, upward sloping rail. This suggests that powered track is needed at this height only to keep a cart climbing. However, the cart slows so much that it can reach only another 5 blocks high with 2 lengths of powered track starting at 9 blocks high. Further testing showed the minimum number of powered blocks to keep the cart climbing well is 3 powered rails every 6 blocks starting at 9 blocks high, at the cost of a strong reduction in speed. To maintain speed in a climb a ratio of 5:4, powered versus regular rail segments, is a good compromise for decent speed at a reasonable cost, starting with 2 powered rails on the flat before the upward slope to be sure the cart starts the climb at maximum speed.

If construction cost is no object one can of course use powered rails all the way to the top to get the best possible performance.

Carts with a rider, or chest carts, have more momentum and so climb higher than one that is unloaded. With a rider, a cart can climb at least 24 blocks before needed powered rails to go higher.

Running a track next to a wall makes no difference to the speed of progress, but an adjacent one-block-high wall significantly slows down a cart if the cart is pointed at the wall while entering a turn or "diagonal" section.

Behavior
Powered rails may be activated by redstone to turn them "on" which makes them able to add momentum to carts already moving over them. When unpowered they are "off" and strongly reduce the momentum of a cart passing over them.

Note that a minecart placed on an active powered rail cannot move as it has no motion for the powered rail to add to. Once the cart is pushed, its rider uses a forward or backward move, or a block placed at one of its ends, the cart's direction of motion is set and the powered rail can affect it.

If a cart is placed on an inactive powered rail that is sloped the braking effect is strong enough to keep it stationary against "gravity". if the powered rail is then turned on gravity is enough to start the cart rolling downhill, which then causes the rail to affect the cart's momentum.

A rail that is "off" slows carts passing over it as if by friction. A single inactive rail is enough to completely halt a cart in most cases. Carts that are loaded and/or at full speed cannot be stopped by just one block, but two "off" rails can stop it. On a long downslope, a stretch of three inactive rails are required to be sure of halting a speeding, loaded cart.

Powering
Power can be transmitted to the rail from any of the six adjacent positions (above, below, or any side) in the same way redstone is powered.

Powered rails propagate power to each other if they are adjacent and part of the same track, for up to 9 blocks from the power source (1 being powered directly which is propagated to 8 adjacent rails). They also receive power from any adjacent detector rails (when a cart passes over it), even if they are not part of the same track (which follows from the rules above). Because the detector rail powers attached rails, it could be used to activate power rails only when necessary:


 * For one-way travel, place a detector rail before the powered rail
 * For two-way travel, place a detector rail on both sides of the powered rail

In practice, it is far more efficient to have powered rails constantly active using other means:


 * Place a redstone torch either next to the powered rail or two blocks underneath it or use powered redstone wiring to achieve the same effect
 * Place an activated lever on the bottom side of the block the powered rail is on (cheapest, requires only a stick and a cobblestone to make)
 * Place the powered rail on a block of redstone

Momentum
The speed of a cart which is boosted using Powered Rails is calculated to be at the maximum of 8 m/s, however, the cart maintains an internal "momentum" value that keeps the cart at the maximum speed of 8 m/s until the excess momentum is depleted.

A single powered rail on the flat ground against a stop block gives an occupied cart enough momentum to travel 80 rail tiles on a flat surface, or 8 tiles for an unoccupied cart (in Beta 1.5, this was 64 blocks and 8 blocks respectively). Tests show that putting several powered rails in a row has observable diminishing returns with each additional powered rail on how much farther a cart travels. This implies that the momentum gained is smaller if the cart's speed is faster and vice versa.

Tests show that climbing slopes impact momentum severely, thus the cart speed plummets fast. However, if there is enough surplus momentum, carts easily travel up slopes. Conversely, carts traveling down slopes gain momentum. Downward sloped powered rails add both the momentum from the rails and the momentum from going downhill to your cart.

Climbing slopes


Launching from rest via four powered rails, an occupied cart has enough momentum to climb a 1/1 slope 10 blocks high without further boosting and then travel horizontally at a very slow speed for at least a dozen blocks before coming to a stop. Such a cart does not have enough momentum to climb an 11 block high slope. An empty cart in a similar setup can climb only 5 blocks and then travel a few blocks horizontally.

When minecarts travel upslope without having sufficient stored momentum, a powered rail is needed 1 every 4 blocks to sustain movement all the way to the top of the slope, Alternatively, 2 every 8 blocks are somewhat easier to supply power to (note that this doesn't seem to be working as of patch 1.14.4, and may require additional testing) However, note this is a worst-case scenario where there is no momentum to start with.

If working with empty carts (for instance, a storage cart transport system), 1 powered every 2 blocks is necessary to sustain the movement. To minimize powering requirements, 2 powered followed by 2 unpowered can also be used (analogous to loaded player-carrying carts).

When traveling up a slope at full speed (8 m/s) one powered rail is sufficient to maintain full speed for two blocks high, meaning that alternating between powered and unpowered rails maintains full speed up a slope. Consecutive powered rails on a slope adds more momentum, so eight powered rails can be followed by 8 normal rails to maintain full speed while traveling up the slope. Less momentum is gained by each consecutive rail as the strip gets longer.

Optimal use
A test was conducted by building straight tracks 2000 blocks long on level ground with different intervals of powered rails. The time to travel the full 2 km length on a player/mob occupied minecart was recorded with each interval. The following table lists the results:

The time to travel the full 2 km length is different for all the other minecart type, requiring more powered rails to reach the top speed of 8 m/s. The following table lists the data collected:. Note that the optimal rail spacing for a fully loaded cart differs, see the original reference for details.

Three powered rails in a row on flat terrain is sufficient to boost all minecart types from rest to the maximum speed of 8 m/s.

Thereafter, the optimal spacing of powered rails on a level track is to use 1 every 38 blocks for occupied carts (that is, a repeating pattern of 1 powered rail followed by 37 normal rails, then another powered rail, and so on) which maintains a constant minecart speed of 7.97 m/s. If gold is in short supply, it is possible to use powered rails with more space between them at the cost of reduced overall speed (see above). If you definitely must have the full 8 m/s you should place a powered rail on a level track 1 every 34 blocks for occupied carts.

For all other (utility) minecart types, the optimal spacing of powered rails on a level track is to use 1 every 27 blocks for empty utility carts (1 powered rail followed by 26 normal rails). A full utility minecart requires much more at 1 every 6 blocks.

An optimal use requires the synchronization of minecart movement and powered rail placement; moving a powered rail a single block forward or back along a track can make a significant difference. This is because the momentum of a minecart is increased per tick (=1/20 of a second) the cart spends on a powered rail (by 0.9 m/s for occupied carts). When a cart travels at the maximum 8 m/s on a straight track, it alternately spends either 2 or 3 ticks on each block. For optimal placement, the powered rail must be put where the cart spends 3 ticks, otherwise, one-third of the boost is wasted.

A diagonal track is a track that consists of the pattern 'left corner' attached to a 'right corner' attached to a 'left corner' and so on. When minecarts travel on a diagonal track, the camera is held steady in the diagonal direction and the minecart visually travels diagonally along the track as well. The speed limit of minecarts is actually 8 m/s per cardinal axis, thus when traveling on 2D tracks, the cart travels 8 m/s in both cardinal directions of travel to result in a net vector of about 11.3 m/s or the square root of 128. With a 3D track, you travel as fast as 13.85 m/s or the square root of 192.

Because of this difference, there is also a difference between the optimal spacing of powered rails when used on a 2D track when compared to straight travel on flat terrain. You need powered rail every 53.7225 (rounded to 54) curved rail. This can be worked out through ratios, comparing 8m/s for 38 rails (the optimal distance for straight rails) to 11.31m/s to work out the value of 53.7225. Therefore for a combination of straight and curved, a curved rail is equivalent to 0.707 of a straight rail. To maintain maximum speed, you must keep the value under 38. For example one combination could be 31 straight rails with 10 curved rails as this is the equivalent of 38 straight rails.

There is also a difference in unmanned or storage minecarts so it is advisable to use a shorter interval if these carts are to be used on the track.

It seems as if the optimally powered rail placing interval to make storage minecarts move is 4 (1 Powered Rail every 4th block). Compared to shorter intervals the reduction in speed is minimal. The maximal possible interval seems to be 9 as the minecart does not reliably reach its destination when using higher intervals.

Usage of detector rails
A detector rail can power 4 adjacent blocks and 2 blocks below it when a minecart, occupied or empty, is on it. This makes it possible to activate powered rails inline without redstone torches or wiring.

A detector can be used to activate adjacent powered rails. However, if the detector is used to activate more than two or three (depending on approach speed) powered rails, the rails deactivate before the minecart reaches them, bringing the cart to an immediate stop.

One-way powered rail lines can be created by placing a detector rail before a powered rail. This way, occupied carts are boosted only if they are traveling the proper direction. Carts going the "wrong" way come to a stop because the powered rail is inactive.

Although inefficient, A two-way rail line can be created by placing detector rails on either side of the powered rail.

Alternately, placing powered and detector rails on a 1×1 slope does not propel a cart more than 3 blocks upward if there is not enough initial momentum. The cart loses too much speed on the incline, meaning it can't make it from the detector rail to the powered rail before the powered rail returns to the "off" state. If the cart is in a train of two or more carts, the last cart in the train becomes stuck instead.

A detector rail could also be used to activate an event based on a cart's location. For example, a fail-safe can be created to release a stopped cart in order to prevent a collision with an arriving cart. The arriving cart passes over a detector rail, activating a powered rail that boosts the resting cart away.

Additional properties


Curved power rails exist in only the case where the final direction is toward the east (with the powered rail appearing in the north-south orientation), or in a T-junction where one path faces east along a north/south track. It is possible to make a one-way curved railway using power rails, but not a bi-directional one.

When placing rails, regular rails prefer to curve toward the powered rail. In cases such as these, the south-west rule applies.

A cart reverses direction when it collides with an object (wall, single block, player, other carts) while traveling on a powered rail. It does not reverse direction if it collides with a translucent block, such as stone slabs or glass. If a track including powered rails is bordered by blocks acting as "buffers", the cart continues back and forth along the track indefinitely. Having carts interact with each other on a short track designed this way can be used to chain multiple carts together as a "train". Once aligned, they all move together at relatively the same speed.

How far the charge passes down adjacent rails is independent of the length of redstone wire. Even if the rails are connected to a redstone torch by 15 blocks of redstone dust, the 8 adjacent rails still receive power despite the fact that they should be out of range for the torch.

Stop points
It is possible to make points in your track where a cart is stopped and then jumpstarted again by player input. This can be useful for creating checkpoints to certain sites of interest in your world. This can be done by using two powered track pieces on a one-block incline, by having the first powered track piece going down, with the second powered track piece at the bottom and a button placed alongside the second powered track piece, so that the button is directly above the track.
 * Stop Point.GIF

When the cart comes to this point, it stops on the incline, allowing the cart to use gravity to start the boost when the button is pushed. Players can then either stay in the cart and carry on to the next stop, or leave the cart at the station for themselves/other players to use later.

A "two-way" stop can be made by combining two of the normal stops with a detector rail in between. This pauses a minecart traveling in either direction and allow them to be restarted by pressing a button.

Starting boost
To create a simple initial boost device using 2 powered rails, dig a hole 1 block deep and 2 blocks long. Place the powered rails inside the trench, connect one end to the track that you wish the minecart to exit. Finally, place the minecart on the powered rail. Once power is applied to the rail, the minecart is boosted out.

When one end of a powered rail has a solid block placed next to it a stationary cart on it gets accelerated away from the block. There are two common ways to exploit this behavior:


 * Unpowered rail at the start of a rail line with a non-transparent block next to it. Place a cart on it and apply a redstone signal to the block to launch the cart.
 * Powered rail at the start of a rail line with a block flush to the ground next to it, and an upward-facing piston under the block. When a cart is placed on the track, a redstone signal to the piston raises the block and to provide the initial push to start the cart moving.

"Whirligig" cyclical minecart accelerator
With simple switching, a minecart can be temporarily diverted into a small loop of powered rails and left there to accelerate. After a delay, which can be achieved with either repeaters or a hopper timer, a second switch can be activated to set the minecart loose down the track. Using this method, with fairly modest delays (in the range of 10-20 seconds) a set of four powered rails can be used to propel a minecart at full speed for several hundred blocks, thus vastly exceeding the efficiency of placing powered rails along the track.

Launcher
Launchers, stations or exits all refer to a point in the system where a rider can safely enter or exit a minecart. They generally use a button to launch the cart.

This first design uses a button, a few powered rails, a bit of redstone wire, and a redstone torch. The button powers the powered rail which launches the cart away from the solid block behind it. In this style of launcher, it is important for an incoming minecart to make it all the way up to the back block so it can easily be launched again.

This second design is essentially the same as the first. A dispenser replaces the solid block behind the last powered rail. The dispenser launches the minecart just like the solid block, but creates a convenient place to store extra minecarts. To activate, use the button behind the dispenser to cause a minecart to pop onto the rail, ready for use.

Rider detection
Players may want to detect whether a cart contains a player, because empty carts can clog a rail system. This is referred to as rider detection.

A trip wire based design is quick to set up and reliably detects a player. However, it doesn't detect some non-player mobs, specifically 'short' mobs (wolves, spiders, pigs, etc.).

To build, a tripwire is attached to hooks one block above the track. Two blocks further is a junction which is set by default to turn empty carts back to the station. An empty minecart does not trigger the tripwire, so it is sent back. An occupied minecart crossing a tripwire sends a short pulse to the junction and continue along the rest of the track.

Depending on orientation, the signal may need to be inverted with a redstone torch. The torch adds a minor delay, but this shouldn't affect the results. This design assumes the minecart is moving at top speed. If your minecart is moving slower than that, you can either add delay to the wire using repeaters or increase the speed of the minecart with a booster just before the tripwire.

Another method to check for a rider is to take advantage of the change in the speed of the cart, as an empty cart slows down more quickly. In this design, a minecart creates a pulse when it passes the detector rail. If the minecart is empty, it gets to the turn just as the signal does and be sent back. If the minecart has a rider, it gets to the turn before the signal and be able to continue on. This design requires the track to be set by default to let the cart through.

Empty carts
When an empty cart is detected, generally it's a good idea to send it into an overflowing pile. An overflow pile is a drop of two or more blocks with a rail at the bottom. When carts are boosted into the hole, they snap to the track, regardless of how many carts are already on the track. This pile should be placed where the carts can be collected, either close to a station or in a maintenance area. It is important to boost carts to full speed just before they are dropped to ensure they don't become stuck on the end of the track and eventually back up the system.

Another variant of this method is to replace the rail at the bottom with a cactus, thus destroying minecarts that fall in. Placement of a hopper next to the sand on which the cactus is placed then allows saving of at least some of the carts.

A dispenser loaded with fire charges break minecart entities, dropping them as items. Placing a detector rail above a hopper, with the dispenser facing the detector rail, collects minecarts as items, which can then be stored in a chest or routed to a cart dispenser.

Boosters
Boosters are a method used to prevent carts from slowing to a stop on a track. Because carts eventually slow to a halt on level track, and very quick turn around on regular rail track while uphill-bound, boosters are a method of assuring one's cart keeps moving. Boosters accelerate carts to a terminal velocity of 8 m/s, as they use powered rails, and help effectively counter the forces of friction and gravity on the acceleration of the cart. Boosters are simply a single powered segment of powered rail, powered through detector rails, redstone torches or levers next to them. Refer to the diagrams to the right. Players generally keep the distance between boosters uniform, although these distances vary by player. One common, and according to many, the most efficient, distribution of powered rails is to place powered rail every 38 blocks on level ground. An easy way to place a lot of track using this count without needing to keep track of each rail is by dividing the rails into stacks of 37, as shown on the right. Approximately 1 out of every 3 rails must be powered to travel uphill due to gravity.

Junction
Stations often have one line leading to one destination. Multiple destinations require multiple lines. A junction is a fork in the track where the rider can select which destination they wish to visit.

This design uses a lever to switch the track. The powered rail becomes powered after a preset delay. The detector rail starts the delay. In this design, the lever always points toward the selected destination regardless of direction.

A junction that has multiple destinations can be set up by expanding the junctions. In the design to the right, the rider is given much more time to select their destination than a two-way junction. They can select any destination by first selecting left or right, then forward or backward. This design doesn't scale well but can be used in sequence to create any number of destinations.

Multiple destination selector
There are many, many styles of minecart destination selectors. Most are modular, meaning they can be extended to include more destinations. An RS-NOR latch array is often used to select a destination as these latches have a designated reset line (as opposed to a t-flip flop which has only one input).

This design was selected for its simplicity and for its ability to be expanded with relative ease. One of the buttons on the selection panel is a designated reset line since additional input doesn't clear the previous selection; that is to say, a player can select more than one destination with this design (although a launched minecart takes the left-most of the selected destinations).

by CNB

The following design is heavily influenced by the previous but uses a different RS-NOR latch design involving pistons. It has a reset integrated in the selection such that a new input clears the previous one. By removing the designated reset line of the previous version, it allows for an additional station in a similar amount of space.

Piston bolt
This consists of a lot of curved tracks and many pistons. The pistons push the minecart extremely quickly down the line.

Troubleshooting
When a track system isn't working properly, it can be difficult to fix for someone unfamiliar with redstone and rails. Common solutions include: Searching on the minecraft forums can help. If you need to create a new post, be sure to include the direction you're working (the F number), as directionality can be a factor in the design.
 * Changing the delay of the circuit by adding a repeater or moving a detector rail to trigger earlier.
 * Changing the speed of the minecart by adding powered rails or moving the current ones further away.
 * Checking that powered rails are powered properly.
 * Turn the design around, as direction can affect how it works. Generally, this isn't the issue, but it's good to rule it out.