Football Table Motion

Introduction

Here we explain MOTION.mdl (aliases/alternate versions: MOTION_demo.mdl, MOTION_exp.mdl, MOTION_demo.mdl and MOTION_test.mdl). MOTION.mdl is compiled as an external and hence you run in from a terminal (as a super user). Compilation is done by running make.m, which is located in the main folder.

The three different version all serve different needs, to use one: save them as MOTION.MDL and compile

MOTION_demo.mdl

Demonstration ready, uses only old code (no Reinforcement learning and a simple policy).

MOTION_frf.mdl

Used for frf-measurements, this by-passes homing and safety, so make sure to center all rods before running. Secondly, check to see if there are actually weak controllers set in this file. The output of this file is the same as all of the variant, a log file called MOTION.mat. An m-file which processes the data can be found in the ../tools folder(determines all transfer functions), you can use the output for loopshaping with i.e.: shape-it.

MOTION_exp.mdl

Experimental version, this file is kept to test new systems e.g. new moves etc.

MOTION_test.mdl

Simulator version, use this file for generating experience. More on this can be found here.

Settings

Enable/Disable Rods

In this subsystem one can disable rods from moving at all, or just allowing them to home. It is recommend to first attempt homing before running the system in its entirety. Do disable/enable rods all you have to do is double-click on them.

Reference generation dialog

In the reference generation dialog we can alter/tweak the homing position and the reference saturation.

Rod number

Number index of the rod, starting with the goal-keeper being rod 1.

Rotational Homing position

Amount of degrees the puppet needs to rotate (for it to be upright) after detecting the homing sensor.

Rotational Homing Velocity

Speed at which to perform the rotational homing.

Translational Homing position.

This is the translation necessary to move to a central positron after hitting the end of its stroke(/side of the table).

Translational Homing Speed

Speed at which to perform the translational homing

Error in translation to determine homing point

This is a threshold, when the error becomes larger then this it assumes it has hit a wall.

Translational saturation

Absolute value at which to saturate the translational reference signal so not to hit the sides.

Safety dialog

The safety has been put in to stop large voltages to be sent as the output for both the translational and rotational controller. Once it exceeds a certain threshold the output is set to zero.

Rod number

Same as before

Maximum rotational voltage

Absolute maximum value of the control signal for rotational controller

Maximum translation voltage

Absolute maximum value of the control signal for translational controller

Maximum rotation

Maximum value of sensor read-outs, if this is exceeded it assumes failure and stops the executable (stop excessive spinning when stability is lost).

Maximum transalation

Maximum value of sensor read-outs, if this is exceeded it assumes failure and stops the executable (happens e.g. a cable snaps).

Building

As said, building the file is really easy and is done using make.m. If this executes properly it will create an executable called MOTION in the main folder. This file currently requires Matlab R2011a (or below), as it makes use of a piece of code which is deprecated in later versions (see `Termination Block' in the simulink model).

When building on a new system, be sure to run setup the compiler correctly by running mex -setup and choosing option 2. Now edit out all the -ansi flags, example:

CFLAGS='-ansi -D_GNU_SOURCE'
Should be:
CFLAGS='-D_GNU_SOURCE'


Also, matlab uses a large set of its own libraries instead of using the system libraries. This can cause problems as we normally compile against system libraries. We fix this by creating some symbolic links to the system libaries (start a terminal):

sudo mv /path/to/matlab/sys/os/gl*/libstdc++.so.6 /path/to/matlab/sys/os/gl*/libstdc++.so.6.back
sudo ln -s /path/to/system/library/libstdc++.so.6 /path/to/matlab/sys/os/gl*/libstdc++.so.6
sudo mv /path/to/matlab/sys/os/gl*/libgfortran.so.3 /path/to/matlab/sys/os/gl*/libgfortran.so.3.back
sudo ln -s /path/to/system/library/libgfortran.so.3 /path/to/matlab/sys/os/gl*/libgfortran.so.3
sudo mv /path/to/matlab/bin/gl*/libcurl.so.4 /path/to/matlab/bin/gl*/libcurl.so.4 back


sudo ln -s /path/to/system/library/libcurl.so.4 /path/to/matlab/bin/gl*/libcurl.so.4

The libraries used by RL/IPC have to be compiled seperately. These can be build by running the src/shm_ipc/install.sh and /src/rl/install.sh.

Running

You can run the motion executable by starting a terminal and typing the following code:

sudo su
cd foosball
./MOTION

When running the external, first homing will take place (apart from MOTION_frf). I recommend first attempting just to home it, by using the enable/disable options explained earlier. Once this is done, it will run until you stop it using ctrl+c, the final time is reached or when the emergency stop is used( not recommended as a default). If it crashes for some reason, or does not home see this section

libmotion_tools

libmotion_tools is a small library created for common calculations performed on the table; puppet selection, intersection point calculation, et cetera. It functions using a class, this class has private variables that remembers what puppet is currently selected. The latter is really useful to avoid hectic switching of puppets in twilight zones.

In this section we shortly describe how to use this library.

motion_tools::get_y_ip(double x, double * q_b)

Determines y-interception point, given a location (x-coordinate) and the ball vector [math]\displaystyle{ Q_b = [x~y~\dot x~\dot y] }[/math].

motion_tools::get_y_ip(double x, double * q_b, int rod_n)

Overloaded method, with added information of the rod number. It determines y-interception point directly usable as reference (puppet selection already done), given a location (x-coordinate) and the ball vector [math]\displaystyle{ Q_b = [x~y~\dot x~\dot y] }[/math].

motion_tools::get_x_ip

Determines x-interception point, given a location (y-coordinate) and the ball vector [math]\displaystyle{ Q_b = [x~y~\dot x~\dot y] }[/math].

motion_tools::get_y_p

Apply puppet selection on a `raw' y-coordinate, yields the y-position usable as reference. This selection is made so that it will only switch puppets if the currently selected puppet cannot reach this position.

motion_tools::get_y_np

Get the position of the puppet that is currently `selected'.

motion_tools::wall_reflect

If an (raw, non-puppet selected) interception point lies outside of the playing field, it will bounce of the wall. This will calculate the new position, based on this reflection.

motion_tools::getsign

Returns the sign of the input.

motion_tools::get_dt

Calculates the time it will take for the ball to reach an interception coordinate (x). This will return a negative number if the interception will never take place.

Actions and Action selection

Selectable actions

Shoot

Variables: Shooting velocity

Tap

Variables: Tapping veloctiy (and direction)

Take

Invariant, to alter change the source file.

Avoid

Variables: duration

Action availability

Action availability is calculated alongside the constraint calculation for the particalur move.

Action selection

Constraints

Attractor dynamics

Other