OpenTx - Key Concepts

Mike Shellim 25 July 2014
Last updated 3 September 2020

Introduction

OpenTx is a uniquely flexible system, and if you've come from a brand like Futaba or Spektrum then you'll find the way of working a little unfamiliar. My aim with this article is to shed some light on how it works, and to enable you to design your own setups with confidence.

I'll cover the following topics:

• An overview of OpenTx
• Sources, mixers, inputs and outputs
• A simple methodology for designing setups

Examples will be illustrated either with screenshots or as text boxes, as appropriate.

Background

OpenTx has just eight programming menus, and each is completely generic. Just like Lego, simple elements are used to build powerful solutions!

But before you can use this power, you'll need to know some of the basics. So let's start at the beginning...

OpenTx: the processing loop

The core of OpenTx (as with any RC system) is the processing loop. This is a sequence of operations repeated several times a second - fast enough to provide a smooth response.

With each cycle, the position of all the controls are read, mixing is applied, and the channel values are calculated. At the end of the cycle, the channel values are passed to the RF module for transmission.

The boxes in blue represent the three key processing steps. These are configured in the 'INPUTS', 'MIXERS' and 'OUTPUTS' menus.

• The MIXERS menu is where you design the control logic (how the system should respond to commands).
• The OUTPUTS menu is for dealing with linkage geometry (setting limits and centres for each servo channel)
• The INPUTS menu is where you set control rates and expo

 

The starting point: Sources

Like all computer programs, OpenTx needs some data to work with. These come from your transmitter's sticks, trims, knobs and switches. A generic term for these is sources. Each source has a unique identifier, for example,

• Ele = elevator stick
• Thr = throttle stick.
• SA = switch 'SA'
• RS = right slider
• S1 = first knob

Each source carries a value between -100 and 100 according to its position. For sticks, left/down is negative; right/up positive. For switches, up is negative, down is positive. Zero corresponds to centre.

So for example,

• Left slider at centre -> LS = 0
• Elevator stick forward -> Ele = 100
• Aileron stick 50% left -> Ail = -50
• Switch SA down -> SA = 100

Source values can be monitored in real time in the ANALOG INPUTS menu. You can use this menu to check that your sticks are calibated correctly.

Channels and outputs

On most radios, a channel corresponds to a servo output. However OpenTx allows you to define up to 32 channels - far more than you're likely to need. In fact, 'channel' has a broader meaning. Here are the key points:

• OpenTx supports up to 32 channels.
• The low channels are normally assigned to servos, ESCs, flight controllers etc, just like any other radio.
• Higher channels can be used for intermediate calculations, with the results cascaded to other channels. Don't worry about this for now.

The OUTPUTS menu

Configuration of channels is done in the OUTPUTS menu. This where you:

• assign a meaningful name.
• set the direction, centres and limits (only necessary for channels which drive a servo)

The screenshot below shows the channels for a simple RES sailplane. The first three have been named 'Rudder', 'Elev' and 'Spoilr'. The travels and centers are at their default values.

The OUTPUTS menu doesn't say how each channel is driven. For that, we need to define some mixers...

Mixers

So far we've talked about sources and channels in isolation. In order to do anything useful, we need link the two using mixers.

Mixers act as the 'wiring' from sources and channels; in other words, they define the control logic.

Unlike mixers in other radios, a mixer in OpenTX is a very simple construct:

• ONE mixer represents ONE interaction between ONE source and ONE channel.

A typical setup will involve anything from a couple of mixers (for an RE sailplane), to literally dozens of mixers (for a full house F3X ship).

The MIXER menu

The list of mixers (max 64) is displayed in the MIXER menu. Each mix has a source, and various parameters such as weight, offset, and curves.

The screenshot below shows a single mix. The source is the aileron stick, and the output is channel 1:

For simple mixes like these, just three columns are displayed:

• Column 3 is the source (stick/knob etc.)
• Column 1 is the channel
• Column 2 is the mixer weight. 100% means maximum effect, 0% means zero effect. A negative weight reverses the effect.

A long press on any line takes you to the mixer editor where you can edit the mix parameters. We'll look at these in more detail later.

Three mixing scenarios

In this section we'll examine three key mixing scenarios. These will form the building blocks of your setups.

Scenario 1: One source -> one channel

This is the simplest scenario. We've already looked at an example where the aileron stick drives CH1:

Scenario 2: One source -> multiple channels

In this scenario, a single source drives more than one channel. In the screenshot below, the aileron stick drives both CH1 and CH5. This is a popular configuration for dual ailerons:

This configuration emulates a Y-lead but is more flexible since each channel can be individually adjusted for direction, travel and centring via the OUTPUTS menu.

Scenario 3: Multiple sources -> one channel

A single channel can also be driven by multiple sources. A common example of this is a V-tail - each surface (channel) is driven by both rudder and elevator sticks:

Note the '+' sign against the Ele line - this indicates that the rudder and elevator inputs are added to produce the output. When using the add operator, the order of the mixers doesn't matter. Other operators like multiply and replace can also be used, and the order for these is important (we'll look at those later).

Designing a mixer scheme

Now that we've covered the basics, let's go straight in and build a complete working system!

The method I will describe can be applied to any model, regardless of complexity. As an example, we'll construct a 2-channel flying wing, controlled using the aileron and elevator sticks.

Step 1. List the sources

The first step is to make a list of the sticks and sliders used to control the model. These will be the sources for the mixers.
The sources for a flying wing are:

• Ail
• Ele
  

Step 2. List the servo channels

The second step is to assign the servo channels.

Our flying wing has two elevon servos. We'll assign these to CH1 and CH2. We can do this directly in the OUTPUTS menu:

Step 3. Identify interactions

Next, we identify the interactions between sticks and channels. An interaction is written as source->channel.

On a flying wing, the Ail stick must affect both elevon surfaces which we've assigned to channels 1 and 2. So,

• Ail -> CH1
• Ail -> CH2

Similarly, the interactions for Ele are:

• Ele -> CH1
• Ele -> CH2

Each line reads as "[source] affects [channel]"

Step 4: Convert interactions into mixer lines

The next step is purely mechanical: simply swap the left and right sides from Step 3.

• CH1 <- Ail
• CH2 <- Ail
• CH1 <- Ele
• CH2 <- Ele

So now, each line can reads as "[channel] is affected by [source]"

Step 5: Reorder interactions by channel number

Now, group the mixer definitions by channel.

• CH1 <- Ail
• CH1 <- Ele

• CH2 <- Ail
• CH2 <- Ele

The mixers are now in the form for entering in the MIXER menu.

Step 6: Enter definitions into the MIXER menu

Finally, created the mixer definitions:

The '+=' means on each line shows that the mixes are additive.

So that's the basics of our flying wing setup. We're not quite finished though, as we haven't taken into account the different effects of the aileron and elevator commands. We do his via the weight parameter.

Setting the mixer weight

The most important mixer parameter is weight. This determines the effect of a mix, between 0 and 100%. The sign determines the direction:

• 100% = full effect (the value of the source if passed through)
• 0% = zero effect (the source is effectively ignored)
• -100% = full reverse effect (the source is reversed)

Applying this to our flying wing:

• we set a higher weight for the aileron mixes (since roll commands require more movement)
• we make one of the aileron weights negative (since the elevons move in opposite directions in response to roll commands).

This basic setup will work fine. However it can be improved, using Inputs.

INPUTS

Our flying wing example above has a shortcoming: in order to adjust stick sensitivity, we have to make the same adjustment in two different mixes:

We can avoid both issues by using Inputs (introduced in OpenTx v. 2.0). An input is like a regular source, but with weight and expo built in. Inputs are distinguished from regular sources by a leading '[I]'.

Inputs are managed in the INPUTS menu.

Amending the flying wing to use Inputs

Using our flying wing example, we create a couple of inputs for the Ail and Ele sticks:

1. Open the INPUTS menu
2. Name the first input as '[I]Ail' and set source = Ail stick.
3. Name the second input as '[I]Ele' and set source = Ele stick.
4. Finally, set weight and expo to the required values
   
   

The [I]Ail and [I]Ele inputs behave exactly like their sources, except they implicitly have 90% weight and 10% expo.

We now amend the mixers to use the new inputs instead of the raw sources:

Note that we have reset the mixer weights to 100% (since the rates are now set in the inputs). When using inputs, set the mixer weights to 100%!

Choosing between raw sources and inputs

The use of inputs is optional. Sometimes it's better to use the raw source. Here are some guidelines:

• Use inputs for any flight controls which use rates and expo. These include the main flight controls: rudder, elevator, aileron sticks.
• Use the raw sources for controls such as motor, spoiler, crow. These typically don't require adjustable rates or expo - adjustments to these willl normally be made in the OUTPUTS menu.

More about inputs

Inputs are an important part of OpenTx, and you can read more about them here.

Mixer calculations

In this section we'll look in more detail at mixer processing. An understanding will be come in useful when debugging your setup.

 

OpenTX performs two sets of calculations. First, individual mixer line values:

Next, the mixer line values are aggregated to produce the mixer outputs. These represent the commanded positions for each channel:

The following table shows the mixer outputs for our flying wing example:

S T I C K S		M I X E R  O U T P U T S
Ail stick	Ele stick	CH1	CH2
(centre) 0	(centre) 0	0	0
(full  right) 100%	(centre) 0	90+0=90	-90+0=-90
(full left) -100%	(centre) 0	-90+0=-90	90+0=90
(centre) 0	(full forward) 100%	0+30=30	0+30=30
(half right) 50%	(half forward) 50%	45+15=60	-45+15=-30
(full  right) 100%	(full forward) 100%	90+30=120	-90+30=-60

The last line shows the effect of "stick in the corner": the mixer output for Channel 1 is 120. In fact, mixer outputs are clipped to +/- 100 in the OUTPUT stage. More on that later.

Mixers monitor

You can see the mixer outputs in real time in the mixers monitor (introduced in OpenTX 2.2). To activate it on the X9D, from the splash screen press {Page} until you get to the channels monitor, then press Enter.

More mixer options

OpenTx offers a number of mixer options. We've already looked at weight. We'll now investigate offset, expo, diff, functions and curves.

The 'offset' parameter

The offset parameter is the most important after weight. Offset is used to shift the mixer output up or down. Using offset in conjunction with weight, you can create mixes whose value varies within defined limits. This is useful for creating volume controls and compensation mixes.

Offset is applied after weight:

Offset example 1: custom volume control

Suppose you want to create volume control (S1), with output varying from -50 to +90 as S1 is rotated. We can do this as follows (remembering that the value of S1 varies from -100 to +100):

Offset example 2: motor-elevator compensation. Offsets are invaluable motor and crow compensation. In these mixes, the mix must be zero at one end of stick travel. To achieve this, weight and offset must have the same magnitude.

The example below shows a typical motor compensation mix. As the throttle stick is advanced, a corrective elevator input is applied up to a maximum of 40% (at full throttle).

Note: offsets should be used sparingly! Don't use them to make ad-hoc adjustments to servo centres - use OUTPUTS->Subtrim for that.

The 'diff', 'expo', 'function' and 'curves' parameters

In addition to weight and offset, OpenTx offers one additional parameter from the following list of choices:

• Diff - reduces the effect by specified %age in one direction
• Expo - applies an expo curve
• Function - e.g. 'x > 0'
• Curve - between 2 and 17 points

The 'Curve' parameter provides the most granularity - it can implement any of the other options, however it requires the most data entry.

How to specify aileron differential

Sailplanes often employ aileron differential in order to reduce the travel of the downgoing aileron.

One source of confusion is the 'diff' parameter, as it's available in both the INPUT and MIXER menus. First, the incorrect way, using INPUTS menu:

Using the above code , the aileron stick will have a higher rate on one side than the other. This is not what we want! Instead, diff must be applied separately to each aileron mix:

To summarise: Do not specify diff at the Input level. Specify diff separately for each aileron mix!

Including/excluding trims

By default, trim values are included in sources. You can exclude trims on a per-mixer basis by unchecking "Include Trim" in the mixer dialog.

For our flying wing example, aileron and elevator trims must always be active, so we'll use the default settings.

Default mixer settings

When you create a new mix, the initial settings are weight=100% and offset=0, diff/expo=0 and no curve. The source value is therefore passed through unchanged.

Order of processing

When calculating a mix line value, OpenTx first applies the trim value. Then it applies the function (diff, function, curve, expo), followed by weight, and finally adds the offset. Order may be important when combining operations especially where offsets are involved!

The OUTPUTS menu

The OUTPUTS menu controls the final stage of processing

In the Output stage, OpenTX performs the following:

1. Clips the incoming mixer values so they lie in the range -100 to +100
2. Applies a scaling and offset

Let's look in more detail:

Clipping

Recall how mixer outputs are aggregated from individual mixer lines:

If several mixers are active, the mixer output may exceed the safe limits of the servo. To prevent this, the OUTPUTS layer clips the value so it lies in the range -100 to +100. Any clipping will manifest itself as deadband at extremes of stick movement.

Scaling and offset

After clipping, a scaling and offset are applied. The scaling and offset are defined by MIN/MAX/SUBTRIM and an optional curve. By setting the output parameters appropriately, you can compensate for differences between the left and right sides of the model.

Notes:

• The curve, if specified, is applied first, then MIN/MAX/SUBTRIM. To avoid confusion when using a curve, it's good practice to leave MIN/MAX/SUBTRIM at 'pass-thru' values (-100/100/0, or -150/150/0 if using extended limits). That way, the curve can be adjusted without consideration to the MIN/MAX/SUBTRIM settings.
• By default, the maximum values for MIN and MAX are -100% and +100%. You can expand this to -150/+150% by specifying Extended Limits in the MODEL SETUP menu.
• A good way of calibrating the servo limits is to generate -100 and +100 channel values, then adjust MIN and MAX for the required servo limits. (Or, if using a curve, adjust the curve end points.)
• Similarly, you calibrate servo centres by generating a channel value of zero, then adjusting SUBTRIM to suit (or, if using a curve, adjust the mid point).

Channels monitor

You can monitor channel outputs in real time, using the Channels monitor.

Where to adjust weights

The three processing layers (Inputs, Mixers, and Outputs) each apply a weight or scaling to their inputs, and these values are cumulative. So final channel output is as follows (ignoring clipping):

OutputValue = SourceValue x Rateinput x Ratemix x Rateoutput

Clearly there is an infinite combination of rates which will produce the same movement at the servo. So where should you set them? Good practice is to adjust servo-related adjustments in the OUTPUTS, control rates in the INPUTS, and as little as possible in the MIXERS!

This is the procedure I recommend:

1. Initialise all weights in MIXERS and INPUTS to 100%.
2. In the OUTPUTS menu, adjust MIN, MAX and SUBTRIM to achieve the required servo limits and centres.
3. In the INPUTS menu, adjust the weights to achieve the desired control surface travel.
4. Any remaining mixer interactions can be adjusted via weights in the MIXERS menu.

More advanced stuff

Mixer operators

We've seen how mixer line values are aggregated to produce mixer outputs. So far, we've only used addition. In fact OpenTx also offers multiplication and replacement operations.

This is very useful. For example, multiplication is key to implementing in-flight adjusters, and 'replace' can be used to implement throttle safety switches.

The operator is specified in the mixers Multiplex parameter, and the options are 'ADD' (the default), 'REPL' and 'MULT'.

When aggregating mixer lines, OpenTx initially assigns a value of zero. Starting at the top line, it steps through each mix, and applying the result according to the multiplex parameter:

• ADD - the mixer value is added to the channel value.
• REPL - the mixer value replaces the channel value.
• MULT - the channel value is multiplied by the mixer value, and the result becomes the new channel value

Note:

• For REPL or MULT ops, the order of the mixer lines is important.
• If a mix is disabled (e.g. via a switch), its ignored.

The following examples illustrate the effect of the various multiplex options. Note the importance of mixer order when using 'REPL' and 'MULT'.

The 'MAX' source

MAX is a special source which doesn't correspond to a physical control. Instead, MAX supplies a fixed value of +100. In conjunction with weight, it can be used to simulate the effect of a fixed stick position.

Here's a simple example, showing a crude motor arming system. The motor is armed when SA is down.

• The Thr line provides variable motor control via the throttle stick
• The MAX line provides a fixed value of -100 corresponding to motor off. The line becomes active when SA is not in the down position (the ! operator in !SA_down means 'not'). When it's active, it overrides the previous line (via the 'multiplex=REPLACE' parameter), and stops the motor.

F3X sailplane mixer scheme

If you're familiar with F3X sailplanes, you may wish to look at interactions and mixes for F3X sailplanes. Such a scheme will normally be optimised by means of Inputs (described later in this article), GVARs and cascading mixers.

Links

LapinFou has produced some useful data flow diagrams which describe the internal workings of OpenTx (Note: at the time of writing, there are one or two errors in the order of processing of curves).