caero-attitude-control/docs.md

Implementation Docs

Redstone Mode

Total redstone inputs: 22 8x tilt signals 6x accelerometer signals 4x direction signals 1x altitude signal 1x downwards thrust signal 1x fore thrust signal 1x aft thrust signal

Total required redstone outputs: at least 8 4x for four large thrusters 8x for at least eight small attitude thrusters (4x lateral, 4x pitch/roll)

Required functionality

• Achieve target angles for tilt values (target is 0)
• Achieve target values for lateral velocity (when no thrust is being applied, 0)
• Achieve target values for for/aft velocity when thrust is applied
• When direction indicators are referenced and autopilot is on, keep all direction indicator values beside "fore" at 0
• A monitor that displays the following values:
  • Directional thrust values (0-15 & 0-100%)
  • Rotational thrust values (0-15 & 0-100%)
  • Velocity values
  • Altitude values
  • Navigation target values (if applicable)
  • Autopilot controls

Create: Avionics relevant Peripheral methods

When Create: Avionics is installed, all sensors get direct peripherals for CC:T

Relevant peripherals:

• Velocity Sensor
• Navigation Table
• Gimbal Sensor
• Altitude Sensor
• Analog Transmission

Altitude Sensor implementations

Peripheral ID: altitude_sensor

• getHeight(): get the sensor's Y coordinate
• getAirPressure(): get the local air pressure at the sensor's altitude
• getVerticalSpeed(): get the sensor's vertical speed (positive is ascending, negative is descending)

Navigation Table implementations

Peripheral ID: navigation_table

• hasTarget(): Check whether the table has resolved a target

• getTargetType(): returns a string target type ID, or nil if no item is held

• getTargetMetadata(): returns per-type metadata for the target.

Metadata schema:

• simulated:compass: kind ("lodestone"|"spawn"), sublevel_id (string, lodestone only)
  • sublevel_id is the tracker UUID
• simulated:recovery_compass: placer_uuid (string, optional)
  • placer_uuid is absent until a player has placed the compass into the table
• simulated:map: map_id (number, optional)
  • map_id is absent if the held map carries no MAP_ID data component (e.g. a blank map)
• simulated:magnet: ---
  • static target (10 blocks north of the table)

• getRelativeAngle(): get the relative angle to the target, in degrees

• getRelativeAngleRad(): get the relative angle to the target, in radians

• getBearing(): get the forward-error bearing to the target, in degrees

  • Forward-error bearing:
    • 0 -> target is straight ahead of the blocks arrow (direct fore)
    • +90 -> target is to the right (direct starboard)
    • -90 -> target is to the left (direct port)
    • +-180 -> target is directly behind (direct aft)

• getBearingRad(): get the forward-error bearing to the target, in randians

• getDistanceToTarget(): get the distance to the resolved target

• getClosureRate(): gets the rate at which the table is closing on the target in blocks/sec (positive is approaching, negative is leaving)

• getVerticalOffsetToTarget(): gets the vertical offset between the target and the table (the difference of target.y - self.y)

• getOrientation(): gets the host sub-level's orientation as a quaternion {x, y, z, w}

Matches JOML's constructor and the convention used by CC quaternion libraries (e.g. TechTastic/Advanced-Math)

• getHeading(): Gets the host sub-level's heading in degrees

0 degrees refers to world +Z, minecraft south

• getHeadingRad(): gets the host sub-level's heading in radians

Gimbal Sensor

Peripheral ID: gimbal_sensor

• getAngles(): get the contraption's pitch and roll angles in degrees
  • xAngle: rotation about body-X (pitch). 0 degrees is aligned with world-up
  • zAngle: rotation about body-Z (roll). 0 degrees is aligned with world-up
  • returns {xAngle, zAngle}
• getAnglesRad(): get the contraption's pitch and roll angles in radians
• getAngularRates(): get the contraption's angular velocity in degrees/sec
  • wx: pitch rate
  • wy: yaw rate
  • wz: roll rate
  • returns {wx, wy, wz}
• getAngularRatesRad(): get the contraption's angular velocity in radians/sec
• getGravity(): gets the local gravity vector in body frame, in m/s^2
  • returns {gx, gy, gz}
• getLinearAcceleration(): get the contraption's proper acceleration in body frame, in m/s^2
  • returns {ax, ay, az}

Velocity Sensor

Peripheral ID: velocity_sensor

• getVelocity(): gets the velocity component along the sensor's axis
  • returns signed velocity in m/s

note: returns 0 if the magnitude is below 0.05 m/s

• getAxis(): returns the body-frame axis the sensor measures along
  • returns string "x", "y", and "z"

Analog Transmission

Peripheral ID: analog_transmission

These are used as controllers for rotationally-powered thruster blocks

• getSignal(): get the current signal driving the transmission ratio
  • returns an integer between 0 and 15
• setSignal(signal): set the signal driving the transmission ratio

Note: flips externallyControlled, even when signal == current

The documented way to get control without changing the value is calling setSignal(getSignal()).

• releaseSignal(): Release external control and return signal driving to redstone
• isExternallyControlled(): Check whether the transmission is currently under script control
• getRotationModifier(): get the current rotation modifier (output:input speed ratio)
• getOutputSpeed(): get the output shaft speed
• getOutputTheoreticalSpeed(): get the output shaft's theoretical (target) speed
• getOutputStressImpact(): get the output-side stress impact (post-ratio kinetic accounting)
• isOversaturated(): check whether the transmission is oversaturated
• getAxis(): get the transmission's shaft axis name
  • returns the axis as string "x", "y", or "z"
• getSelfId(): get this block's ID

Note: other peripherals' getSourceId or getSubnetworkAnchorId will return this ID when they refer to this block

• getSourceId(): get the ID of the block immediately driving this one, or nil if theis block has no source
• getSubnetworkAnchorId(): get the ID of this block's speed-zone anchor -- the gearshift/clutch/speed controller/generator that defines the start of this speed zone.

Note: Two blocks share an anchor if they're in the same speed zone. A generator or split-shaft returns its own getSelfId()

• getNetworkId(): get the ID of this block's kinetic network.
• getKind(): returns one of "generator", "split_shaft", "consumer", or "passthrough"
• getSpeed(): get the local rotational speed at this block.
• hasSource(): check whether this block is connected to a kinetic source
• isOverstressed(): check whether this block's network is overstressed
• getStressImpact(): get the stress impact of this block on its network. zero for sources and pure conduit blocks
• getStressContribution(): get this block's contribution to its network's stress capacity. Non-zero for sources only

Peripheral Notes

• Analog Transmissions signal speed changes:
  • 0: no change from input speed
  • 14: maximum change from input speed
  • 15: input and output rotational networks are decoupled (generally means no output rotation)
  • All that is to say, when being driven properly, the minimum speed is at signal 15, and increasing the speed goes from the lowest nonzero RPM at signal 0 to the highest at signal 14.

Implementation

On startup, call these methods:

• All Analog Transmission's getSelfId()
• All rotationally controlled thruster's getSubnetworkAnchorId()

If the ID returned by a thruster's getSubnetworkAnchorId() is also returned by an analog transmission's getSelfId(), associated that transmission with the thruster

Also upon startup, check for a configuration file with other thruster's peripherals, or redstone-controlled thrusters

Every cycle:

• Check for new machines in the network. If new machines are found, initialize them similarly to the startup

• Gimbal Sensor getAngles(), getAngularRates(), and getLinearAcceleration()

• Navigation Table getHeading(), hasTarget(), and depending on the output of hasTarget():

  • if true, call getBearing(), getDistanceToTarget(), getClosureRate(), and getVerticalOffsetToTarget()
  • if false, continue to the next sensors

• Altitude Sensor getHeight(), getAirPressure(), getVerticalSpeed()

• Velocity Sensor getAxis(), getVelocity

• Poll input signal strengths for global downwards thrust, and fore and aft thrust