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22 KiB
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INAV Programming Framework
INAV Programming Framework (IPF) is a mechanism that allows you to to create custom functionality in INAV. You can choose for certain actions to be done, based on custom conditions you select.
Logic conditions can be based on things such as RC channel values, switches, altitude, distance, timers, etc. The conditions you create can also make use of other conditions you've entered previously. The results can be used in:
- Servo mixer to activate/deactivate certain servo mix rulers
- To activate/deactivate system overrides
INAV Programming Framework consists of:
- Logic Conditions - each Logic Condition can be understood as a single command, a single line of code. Each logic condition consists of:
- an operator (action), such as "plus" or "set vtx power"
- one or two operands (nouns), which the action acts upon. Operands are often numbers, such as a channel value or the distance to home.
- "activator" condition - optional. This condition is only active when another condition is true
- Global Variables - variables that can store values from and for Logic Conditions and servo mixer
- Programming PID - general purpose, user configurable PID controllers
IPF can be edited using INAV Configurator user interface, or via CLI. To use COnfigurator, click the tab labeled "Programming". The various options shown in Configurator are described below.
Logic Conditions
CLI
logic <rule> <enabled> <activatorId> <operation> <operand A type> <operand A value> <operand B type> <operand B value> <flags>
<rule>- ID of Logic Condition rule<enabled>-0evaluates as disabled,1evaluates as enabled<activatorId>- the ID of LogicCondition used to activate this Condition. Logic Condition will be evaluated only then Activator evaluates astrue.-1evaluates astrue<operation>- SeeOperationsparagraph<operand A type>- SeeOperandsparagraph<operand A value>- SeeOperandsparagraph<operand B type>- SeeOperandsparagraph<operand B value>- SeeOperandsparagraph<flags>- SeeFlagsparagraph
Operations
| Operation ID | Name | Notes |
|---|---|---|
| 0 | TRUE | Always evaluates as true |
| 1 | EQUAL | Evaluates false if false or 0 |
| 2 | GREATER_THAN | true if Operand A is a higher value than Operand B |
| 3 | LOWER_THAN | true if Operand A is a lower value than Operand B |
| 4 | LOW | true if <1333 |
| 5 | MID | true if >=1333 and <=1666 |
| 6 | HIGH | true if >1666 |
| 7 | AND | true if Operand A and Operand B are the same value or both true |
| 8 | OR | true if Operand A and/or OperandB is true |
| 9 | XOR | true if Operand A or Operand B is true, but not both |
| 10 | NAND | false if Operand A and Operand B are both true |
| 11 | NOR | true if Operand A and Operand B are both false |
| 12 | NOT | The boolean opposite to Operand A |
| 13 | Sticky | Operand A is the activation operator, Operand B is the deactivation operator. After the activation is true, the operator will return true until Operand B is evaluated as true |
| 14 | Basic: Add | Add Operand A to Operand B and returns the result |
| 15 | Basic: Subtract | Substract Operand B from Operand A and returns the result |
| 16 | Basic: Multiply | Multiply Operand A by Operand B and returns the result |
| 17 | Basic: Divide | Divide Operand A by Operand B and returns the result |
| 18 | Set GVAR | Store value from Operand B into the Global Variable addressed by |
Operand A. Bear in mind, that operand Global Variable means: Value stored in Global Variable of an index! To store in GVAR 1 use Value 1 not Global Variable 1 |
||
| 19 | Increase GVAR | Increase the GVAR indexed by Operand A (use Value 1 for Global Variable 1) with value from Operand B |
| 20 | Decrease GVAR | Decrease the GVAR indexed by Operand A (use Value 1 for Global Variable 1) with value from Operand B |
| 21 | Set IO Port | Set I2C IO Expander pin Operand A to value of Operand B. Operand A accepts values 0-7 and Operand B accepts 0 and 1 |
| 22 | OVERRIDE_ARMING_SAFETY | Allows the craft to arm on any angle even without GPS fix. WARNING: This bypasses all safety checks, even that the throttle is low, so use with caution. If you only want to check for certain conditions, such as arm without GPS fix. You will need to add logic conditions to check the throttle is low. |
| 23 | OVERRIDE_THROTTLE_SCALE | Override throttle scale to the value defined by operand. Operand type 0 and value 50 means throttle will be scaled by 50%. |
| 24 | SWAP_ROLL_YAW | basically, when activated, yaw stick will control roll and roll stick will control yaw. Required for tail-sitters VTOL during vertical-horizonral transition when body frame changes |
| 25 | SET_VTX_POWER_LEVEL | Sets VTX power level. Accepted values are 0-3 for SmartAudio and 0-4 for Tramp protocol |
| 26 | INVERT_ROLL | Inverts ROLL axis input for PID/PIFF controller |
| 27 | INVERT_PITCH | Inverts PITCH axis input for PID/PIFF controller |
| 28 | INVERT_YAW | Inverts YAW axis input for PID/PIFF controller |
| 29 | OVERRIDE_THROTTLE | Override throttle value that is fed to the motors by mixer. Operand is scaled in us. 1000 means throttle cut, 1500 means half throttle |
| 30 | SET_VTX_BAND | Sets VTX band. Accepted values are 1-5 |
| 31 | SET_VTX_CHANNEL | Sets VTX channel. Accepted values are 1-8 |
| 32 | SET_OSD_LAYOUT | Sets OSD layout. Accepted values are 0-3 |
| 33 | Trigonometry: Sine | Computes SIN of Operand A value in degrees. Output is multiplied by Operand B value. If Operand B is 0, result is multiplied by 500 |
| 34 | Trigonometry: Cosine | Computes COS of Operand A value in degrees. Output is multiplied by Operand B value. If Operand B is 0, result is multiplied by 500 |
| 35 | Trigonometry: Tangent | Computes TAN of Operand A value in degrees. Output is multiplied by Operand B value. If Operand B is 0, result is multiplied by 500 |
| 36 | MAP_INPUT | Scales Operand A from [0 : Operand B] to [0 : 1000]. Note: input will be constrained and then scaled |
| 37 | MAP_OUTPUT | Scales Operand A from [0 : 1000] to [0 : Operand B]. Note: input will be constrained and then scaled |
| 38 | RC_CHANNEL_OVERRIDE | Overrides channel set by Operand A to value of Operand B. Note operand A should normally be set as a "Value", NOT as "Get RC Channel" |
| 39 | SET_HEADING_TARGET | Sets heading-hold target to Operand A, in degrees. Value wraps-around. |
| 40 | Modulo | Modulo. Divide Operand A by Operand B and returns the remainder |
| 41 | LOITER_RADIUS_OVERRIDE | Sets the loiter radius to Operand A [0 : 100000] in cm. If the value is lower than the loiter radius set in the Advanced Tuning, that will be used. |
| 42 | SET_PROFILE | Sets the active config profile (PIDFF/Rates/Filters/etc) to Operand A. Operand A must be a valid profile number, currently from 1 to 3. If not, the profile will not change |
| 43 | Use Lowest Value | Finds the lowest value of Operand A and Operand B |
| 44 | Use Highest Value | Finds the highest value of Operand A and Operand B |
| 45 | FLIGHT_AXIS_ANGLE_OVERRIDE | Sets the target attitude angle for axis. In other words, when active, it enforces Angle mode (Heading Hold for Yaw) on this axis (Angle mode does not have to be active). Operand A defines the axis: 0 - Roll, 1 - Pitch, 2 - Yaw. Operand B defines the angle in degrees |
| 46 | FLIGHT_AXIS_RATE_OVERRIDE | Sets the target rate (rotation speed) for axis. Operand A defines the axis: 0 - Roll, 1 - Pitch, 2 - Yaw. Operand B defines the rate in degrees per second |
| 47 | EDGE | Momentarily true when triggered by Operand A. Operand A is the activation operator [boolean], Operand B (Optional) is the time for the edge to stay active [ms]. After activation, operator will return true until the time in Operand B is reached. If a pure momentary edge is wanted. Just leave Operand B as the default Value: 0 setting. |
| 48 | DELAY | Delays activation after being triggered. This will return true when Operand A is true, and the delay time in Operand B [ms] has been exceeded. |
| 49 | TIMER | A simple on - off timer. true for the duration of Operand A [ms]. Then false for the duration of Operand B [ms]. |
| 50 | DELTA | This returns true when the value of Operand A has changed by the value of Operand B or greater within 100ms. |
| 51 | APPROX_EQUAL | true if Operand B is within 1% of Operand A. |
| 52 | LED_PIN_PWM | Value Operand A from [0 : 100] starts PWM generation on LED Pin. See LED pin PWM. Any other value stops PWM generation (stop to allow ws2812 LEDs updates in shared modes) |
Operands
| Operand Type | Name | Notes |
|---|---|---|
| 0 | VALUE | Value derived from value field |
| 1 | GET_RC_CHANNEL | value points to RC channel number, indexed from 1 |
| 2 | FLIGHT | value points to flight parameter table |
| 3 | FLIGHT_MODE | value points to flight modes table |
| 4 | LC | value points to other logic condition ID |
| 5 | GVAR | Value stored in Global Variable indexed by value. GVAR 1 means: value in GVAR 1 |
| 5 | PID | Output of a Programming PID indexed by value. PID 1 means: value in PID 1 |
FLIGHT
| Operand Value | Name | Notes |
|---|---|---|
| 0 | ARM_TIMER | in seconds |
| 1 | HOME_DISTANCE | in meters |
| 2 | TRIP_DISTANCE | in meters |
| 3 | RSSI | |
| 4 | VBAT | in Volts * 100, eg. 12.1V is 1210 |
| 5 | CELL_VOLTAGE | in Volts * 100, eg. 12.1V is 1210 |
| 6 | CURRENT | in Amps * 100, eg. 9A is 900 |
| 7 | MAH_DRAWN | in mAh |
| 8 | GPS_SATS | |
| 9 | GROUD_SPEED | in cm/s |
| 10 | 3D_SPEED | in cm/s |
| 11 | AIR_SPEED | in cm/s |
| 12 | ALTITUDE | in cm |
| 13 | VERTICAL_SPEED | in cm/s |
| 14 | TROTTLE_POS | in % |
| 15 | ATTITUDE_ROLL | in degrees |
| 16 | ATTITUDE_PITCH | in degrees |
| 17 | IS_ARMED | boolean 0/1 |
| 18 | IS_AUTOLAUNCH | boolean 0/1 |
| 19 | IS_ALTITUDE_CONTROL | boolean 0/1 |
| 20 | IS_POSITION_CONTROL | boolean 0/1 |
| 21 | IS_EMERGENCY_LANDING | boolean 0/1 |
| 22 | IS_RTH | boolean 0/1 |
| 23 | IS_LANDING | boolean 0/1 |
| 24 | IS_FAILSAFE | boolean 0/1 |
| 25 | STABILIZED_ROLL | Roll PID controller output [-500:500] |
| 26 | STABILIZED_PITCH | Pitch PID controller output [-500:500] |
| 27 | STABILIZED_YAW | Yaw PID controller output [-500:500] |
| 28 | 3D HOME_DISTANCE | in meters, calculated from HOME_DISTANCE and ALTITUDE using Pythagorean theorem |
| 29 | CROSSFIRE LQ | Crossfire Link quality as returned by the CRSF protocol |
| 30 | CROSSFIRE SNR | Crossfire SNR as returned by the CRSF protocol |
| 31 | GPS_VALID | boolean 0/1. True when the GPS has a valid 3D Fix |
| 32 | LOITER_RADIUS | The current loiter radius in cm. |
| 33 | ACTIVE_PROFILE | integer for the active config profile [1..MAX_PROFILE_COUNT] |
| 34 | BATT_CELLS | Number of battery cells detected |
| 35 | AGL_STATUS | boolean 1 when AGL can be trusted, 0 when AGL estimate can not be trusted |
| 36 | AGL | integer Above The Groud Altitude in cm |
| 37 | RANGEFINDER_RAW | integer raw distance provided by the rangefinder in cm |
| 38 | ACTIVE_MIXER_PROFILE | Which mixers are currently active (for vtol etc) |
| 39 | MIXER_TRANSITION_ACTIVE | Currently switching between mixers (quad to plane etc) |
| 40 | ATTITUDE_YAW | current heading (yaw) in degrees |
| 41 | FW Land Sate | integer 1 - 5, indicates the status of the FW landing, 0 Idle, 1 Downwind, 2 Base Leg, 3 Final Approach, 4 Glide, 5 Flare |
FLIGHT_MODE
The flight mode operands return true when the mode is active. These are modes that you will see in the Modes tab. Note: the USER* modes are used by camera switchers, PINIO etc. They are not the Waypoint User Actions. See the Waypoints section to access those.
| Operand Value | Name | Notes |
|---|---|---|
| 0 | FAILSAFE | true when a Failsafe state has been triggered. |
| 1 | MANUAL | true when you are in the Manual flight mode. |
| 2 | RTH | true when you are in the Return to Home flight mode. |
| 3 | POSHOLD | true when you are in the Position Hold or Loiter flight modes. |
| 4 | CRUISE | true when you are in the Cruise flight mode. |
| 5 | ALTHOLD | true when you the Altitude Hold flight mode modifier is active. |
| 6 | ANGLE | true when you are in the Angle flight mode. |
| 7 | HORIZON | true when you are in the Horizon flight mode. |
| 8 | AIR | true when you the Airmode flight mode modifier is active. |
| 9 | USER1 | true when the USER 1 mode is active. |
| 10 | USER2 | true when the USER 2 mode is active. |
| 11 | COURSE_HOLD | true when you are in the Course Hold flight mode. |
| 12 | USER3 | true when the USER 3 mode is active. |
| 13 | USER4 | true when the USER 4 mode is active. |
| 14 | ACRO | true when you are in the Acro flight mode. |
| 15 | WAYPOINT_MISSION | true when you are in the WP Mission flight mode. |
WAYPOINTS
| Operand Value | Name | Notes |
|---|---|---|
| 0 | Is WP | Boolean 0/1 |
| 1 | Current Waypoint Index | Current waypoint leg. Indexed from 1. To verify WP is in progress, use Is WP |
| 2 | Current Waypoint Action | true when Action active in current leg. See ACTIVE_WAYPOINT_ACTION table |
| 3 | Next Waypoint Action | true when Action active in next leg. See ACTIVE_WAYPOINT_ACTION table |
| 4 | Distance to next Waypoint | Distance to next WP in metres |
| 5 | Distance from Waypoint | Distance from the last WP in metres |
| 6 | User Action 1 | true when User Action 1 is active on this waypoint leg [boolean 0/1] |
| 7 | User Action 2 | true when User Action 2 is active on this waypoint leg [boolean 0/1] |
| 8 | User Action 3 | true when User Action 3 is active on this waypoint leg [boolean 0/1] |
| 9 | User Action 4 | true when User Action 4 is active on this waypoint leg [boolean 0/1] |
| 10 | Next Waypoint User Action 1 | true when User Action 1 is active on the next waypoint leg [boolean 0/1] |
| 11 | Next Waypoint User Action 2 | true when User Action 2 is active on the next waypoint leg [boolean 0/1] |
| 12 | Next Waypoint User Action 3 | true when User Action 3 is active on the next waypoint leg [boolean 0/1] |
| 13 | Next Waypoint User Action 4 | true when User Action 4 is active on the next waypoint leg [boolean 0/1] |
ACTIVE_WAYPOINT_ACTION
| Action | Value |
|---|---|
| WAYPOINT | 1 |
| HOLD_TIME | 3 |
| RTH | 4 |
| SET_POI | 5 |
| JUMP | 6 |
| SET_HEAD | 7 |
| LAND | 8 |
Flags
All flags are reseted on ARM and DISARM event.
| bit | Decimal | Function |
|---|---|---|
| 0 | 1 | Latch - after activation LC will stay active until LATCH flag is reset |
| 1 | 2 | Timeout satisfied - Used in timed operands to determine if the timeout has been met |
Global variables
CLI
gvar <index> <default value> <min> <max>
Programming PID
pid <index> <enabled> <setpoint type> <setpoint value> <measurement type> <measurement value> <P gain> <I gain> <D gain> <FF gain>
<index>- ID of PID Controller, starting from0<enabled>-0evaluates as disabled,1evaluates as enabled<setpoint type>- SeeOperandsparagraph<setpoint value>- SeeOperandsparagraph<measurement type>- SeeOperandsparagraph<measurement value>- SeeOperandsparagraph<P gain>- P-gain, scaled to1/1000<I gain>- I-gain, scaled to1/1000<D gain>- D-gain, scaled to1/1000<FF gain>- FF-gain, scaled to1/1000
Examples
When more than 100 meters away, increase VTX power
When more than 600 meters away, engage return-to-home by setting the matching RC channel
Dynamic THROTTLE scale
logic 0 1 0 23 0 50 0 0 0
Limits the THROTTLE output to 50% when Logic Condition 0 evaluates as true
Set VTX power level via Smart Audio
logic 0 1 0 25 0 3 0 0 0
Sets VTX power level to 3 when Logic Condition 0 evaluates as true
Invert ROLL and PITCH when rear facing camera FPV is used
Solves the problem from https://github.com/iNavFlight/inav/issues/4439
logic 0 1 0 26 0 0 0 0 0
logic 1 1 0 27 0 0 0 0 0
Inverts ROLL and PITCH input when Logic Condition 0 evaluates as true. Moving Pitch stick up will cause pitch down (up for rear facing camera). Moving Roll stick right will cause roll left of a quad (right in rear facing camera)
Cut motors but keep other throttle bindings active
logic 0 1 0 29 0 1000 0 0 0
Sets throttle output to 0% when Logic Condition 0 evaluates as true
Set throttle to 50% and keep other throttle bindings active
logic 0 1 0 29 0 1500 0 0 0
Sets throttle output to about 50% when Logic Condition 0 evaluates as true
Set throttle control to different RC channel
logic 0 1 0 29 1 7 0 0 0
If Logic Condition 0 evaluates as true, motor throttle control is bound to RC channel 7 instead of throttle channel
Set VTX channel with a POT
Set VTX channel with a POT on the radio assigned to RC channel 6
logic 0 1 -1 15 1 6 0 1000 0
logic 1 1 -1 37 4 0 0 7 0
logic 2 1 -1 14 4 1 0 1 0
logic 3 1 -1 31 4 2 0 0 0
Steps:
- Normalize range
[1000:2000]to[0:1000]by substracting1000 - Scale range
[0:1000]to[0:7] - Increase range by
1to have the range of[1:8] - Assign LC#2 to VTX channel function
Set VTX power with a POT
Set VTX power with a POT on the radio assigned to RC channel 6. In this example we scale POT to 4 power level [1:4]
logic 0 1 -1 15 1 6 0 1000 0
logic 1 1 -1 37 4 0 0 3 0
logic 2 1 -1 14 4 1 0 1 0
logic 3 1 -1 25 4 2 0 0 0
Steps:
- Normalize range [1000:2000] to [0:1000] by substracting
1000 - Scale range [0:1000] to [0:3]
- Increase range by
1to have the range of [1:4] - Assign LC#2 to VTX power function
Common issues / questions about IPF
One common mistake involves setting RC channel values. To override (set) the value of a specific RC channel, choose "Override RC value", then for operand A choose value and enter the channel number. Choosing "get RC value" is a common mistake, which does something other than what you probably want.
