Description
For the seventh and final programming assignment, you will implement a reinforcement learner and apply
it to the racetrack problem. The racetrack problem is a standard control problem. The goal is to control
the movement of a race car along a pre-defined racetrack. You want your race car to get from the starting
line to the finish line in a minimum amount of time. In this version of the problem, your agent will be the
only racer on the track, so it is more like a time trial than a full competitive race.
More formally, at each time step, the state of the agent can be encoded in four variables: xt and yt are
the x and y coordinates corresponding to the location of the car at time step t (we treat the racetrack as
being layed out on a Cartesian grid). The variables x˙ t and y˙t represent the x and y components of the car’s
velocity at time t. The control variables for the car are ax and ay, which represent the x and y components
of an acceleration vector to be applied at the current time step. The system is governed by an approximation
of the standard laws of kinematics:
xt ≡ x position
yt ≡ y position
x˙ t = xt − xt−1 ≡ x speed
y˙t = yt − yt−1 ≡ y speed
axt = ¨xt = ˙xt − x˙ t−1 ≡ x acceleration
ayt = ¨yy = ˙yt − y˙t−1 ≡ y acceleration
At any given time step, your car only has active control over the values of ax and ay and must use these
control variables to influence the car’s state. This essentially gives you the ability to accelerate, decelerate,
and turn. There is a further restriction that the set of values that may be assigned to a control variable is
−1, 0, and 1. That is,
a{x,y} ∈ {−1, 0, 1}.
The velocity of your car at any given time is limited to ( ˙xt, y˙t) ∈ [±5, ±5]. Any attempt to accelerate or
decelerate beyond these limits will be ignored.
As an example, if at time t = 0 your car is at location (2, 2) with velocity (1, 0), it is essentially moving
towards the east. If you apply an acceleration of (1, 1), then at timestep t = 1 your position will be (4, 3)
and your velocity will be (2, 1). At each time step, your acceleration is applied to your velocity before your
position is updated. Strictly speaking, this is not a good model of Newtonian physics, but we’re dealing with
integer position and velocity values, so some simplifying abstractions need to be made.
If this were the extent of the problem, it would be quite easy to solve for any given track, so to make
things a bit more interesting, we are going add in a small amount of non-determinism. To do this, we assign
a probability to each attempted action for each possible outcome. For this assignment, we specify that for
any attempt to accelerate, there is a 20% chance that attempt will simply fail, and the velocity will remain
unchanged at the next timestep. Thus, at each timestep, the probability of accelerating as specified is 80%
and the probability of having no acceleration is 20%.
In this problem, there is an additional requirement that you stay on the track; crashing into the wall is
bad. You will experiment with two different versions of how “bad” it is to crash. The first variant says that,
if the car crashes into a wall, it is placed at the nearest position on the track to the place where it crashed,
and its velocity is set to (0, 0). The second, harsher variant says that when a car crashes, its position is set
back to the original starting position, as well as zeroing its velocity. Essentially, in this latter case if you
crash, you have to start over from the beginning. You should implement both variants in your program so
that you can experiment with what effects they have on the strategies your car learns. Since you have a
limited time to run experiments, however, you are only expected to do a side by side comparison of the two
definitions of a “crash” on the R shaped track (in the file R-track.txt). For the other tracks, use the version
where crashing stops the car but leaves it in the location it crashed.
The cost function is 1 for each move, except when you reach the finish line. The finish line locations are
absorbing states with cost 0. Since you are attempting to minimize cost, this translates to attempting to
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complete the race in as few time steps as possible. You do not need to stop on a finish state. It is sufficient
to cross the finish line, so this means the “wall” behind the finish line really isn’t a wall.
Here are the specific steps that need to be followed.
• Implement the racetrack problem as described above, including a racing simulator that takes a track
specification (described below).
• Implement the Value Iteration algorithm and either the Q-learning or SARSA algorithm, and apply
them to the racetrack problem.
• For extra credit (for up to 10 additional points), implement both Q-learning and SARSA and apply
them to the racetrack problem.
• For extra credit (for up to 20 additional points), implement TD-learning with function approximation
(i.e., with a feedforward neural network) and apply it to the racetrack problem.
• Test your algorithms on the two of the three provided tracks in the data files described below. One
of the tracks must be the R-track, but you can choose between the L-track and the O-track. The files
are named L-track.txt, O-track.txt, and R-track.txt and can be found within Blackboard. Test
your algorithms on each of the two crash scenarios. It is up to you to determine appropriate design
parameters such as learning rate, discount factor, exploration strategy, etc.
• Use the data files for the tracks provided, represented in ASCII. The first line lists the size of the track
as an comma delimited pair hrows, colsi. The rest of the file is a grid of the specified dimensions with
one character at each point. The legend for the files is:
– S – This square is on the starting line.
– F – This square is on the finish line.
– . – This square is open racetrack.
– # – This square is off the racetrack (i.e., a wall).
As a simple example: 5,5
FF###
..###
..###
….S
….S
• Run experiments, keeping track of the number of training iterations and the number of steps the race
car needs to take before finding the finish line. Make sure you run at least 10 experiments for each
track (preferably more) to get reasonable statistics. Also generate data so you can plot learning curves.
• Write a paper that incorporates the following elements, summarizing the results of your experiments.
Make sure you explain the experimental setup, the tuning process, and the final parameters used for
each algorithm.
1. Title and author names
2. A brief, one paragraph abstract summarizing the results of the experiments
3. Problem statement, including hypothesis (how do you expect the algorithms to do?)
4. Description of algorithms implemented
5. Description of your experimental approach
6. Presentation of the results of your experiments
7. A discussion of the behavior of your algorithms, combined with any conclusions you can draw
8. Summary
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9. References
• Submit your fully documented code with sample runs, results of the runs of each algorithm, and your
paper. Your grade will be broken down as follows:
– Code structure – 10%
– Code documentation/commenting – 10%
– Proper functioning of your code, as illustrated by sample runs – 30%
– Summary paper – 50%
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