COS126

Introduction

Goals:

Learn about a scientific computing application.
Learn about reading input using the StdIn library and printing formatted output using the StdOut library.
Learn about plotting graphics using the StdDraw library.
Learn about using the command line to redirect standard input to read from a file.
Use arrays.

Operating System and Configuration

I used the auto-installer, but when I compile in Terminal, the Java compiler reports that it cannot resolve symbol StdDraw. Why is this? Be sure to use the wrapper commands javac-introcs and java-introcs (instead of javac and java); these wrapper commands tell Java where to find our standard libraries. If you are using the wrapper commands, try re-rerunning the autoinstaller; this should fix situations where you moved files that the auto-installer added. Otherwise, check with a lab TA.

FAQ

What preparation do I need before beginning this assignment? Read Sections 1.4 and 1.5 of the textbook and familiarize yourself with the IntelliJ embedded terminal commands.

For help with standard input, review Students.java. Compile and execute to make sure your system is configured properly. You can use students.txt as input.
For help with standard drawing, review DeluxeBouncingBall.java. There are many methods in StdDraw, but for this assignment, you won't need only those in DeluxeBouncingBall.java. Compile and execute to make sure your system is configured properly. You will need laser.wav and pop.wav.

Any advice on completing this programming assignment? This program is more involved than the previous ones, so you should budget more time accordingly. The best advice we can give you is to carefully test, debug, and re-test your code as you write it. Do not attempt to write the whole program at once—if you do, then you will have no idea where to find the errors when the program doesn't work. Proactive testing will save you enormous amounts of time in the long run. Trust us!

Do I have to follow the assignment specifications for reading input from command-line arguments and standard input, and writing output to standard drawing and standard output? Yes, or you will lose a substantial number of points.

Where can I find the APIs for StdIn, StdOut, StdDraw, and StdAudio? They are on pp. 1140–1141 of the textbook. They also appear in this Java cheatsheet.

How do I draw an image to standard drawing? The command StdDraw.picture(x, y, filename) reads the image (either JPEG, GIF, or PNG format) from the specified file and draws it to standard drawing, centered at (x, y).

Simulation

Can I combine Steps A, B, and C for each body? No, as indicated in the assignment, you must separate Step A (calculate all of the forces) from Step B (update the velocities and positions); otherwise, you will be computing the forces at time t using the velocities and positions of some of bodies at time t and others at time t + Δt.

What is Δx? It's the change in x-coordinate between two bodies (not between a body at time t and at time t + Δt).

How many steps should my program simulate if Τ is not a multiple of Δt? Simulate the universe as long as t < Τ. For example, if Τ is 50,000 and Δt is 25,000, you should simulate the system for two steps (t = 0 and 25,000). If Τ is 60,000 and Δt is 25,000, you should simulate the system for three steps (t = 0, 25,000 and 50,000).

Does my program need to plot anything if T equals 0? No.

Errors and Bugs

Checkstyle complains about the variable I named T because it begins with an uppercase letter. Which name should I use instead? By convention, a variable in Java should begin with a lowercase letter and use camel case, such as isLeapYear. A constant variable (a variable whose value does not change during the execution of a program, or from one execution of the program to the next) should begin with an uppercase letter and use underscores to separate any word boundaries, such as GRAVITATIONAL_CONSTANT. So, a Java variable name might not always perfect align with the corresponding domain-specific mathematical notation. In this case, tao or stoppingTime would be fine choices.

Why do I get an InputMismatchException or a NoSuchElementException when I read data using StdIn?

InputMismatchException means that your program is attempting to read data of one type but the next piece of data on standard input is of an incompatible type. For example, if you use StdIn.readInt() and the next token on standard input is 3.14.
NoSuchElementException means that your program is trying to read data from standard input when there is no more data available from standard input. For example, if you use StdIn.readInt() to read two integers but standard input contains only a single integer. (This can also happen if you wipe out an input file, such as planets.txt, by errantly typing > instead of a < during a redirection command.)

My computer doesn't display the animation smoothly. Is there anything I can do? Be sure to follow the template in BouncingBall.java. In particular, call StdDraw.enableDoubleBuffering() once at the beginning of your program; and call StdDraw.show() and StdDraw.pause(20) at the end of each time step (frame), not after each call to StdDraw.picture().

My animation looks fine, but the numbers are off a little bit when I follow the tests below, what could be causing this? Check that you followed the assignment instructions exactly. In particular, you should have separate loops for Steps A, B, and C and you should update the velocities before the positions in Step B.

I draw the bodies, but they do not appear on the screen. Why? Did you use StdDraw.setXscale() and StdDraw.setYscale() to change the x- and y-coordinate systems to use the physics coordinates instead of the unit box? Since you want it centered on the origin with a "square radius" of radius, the minimum of each axis should be –radius and the maximum should be +radius.

My bodies repel each other. Why don't they attract each other? Make sure that you get the sign right when you apply Newton's law of gravitation: (x[j] - x[i]) vs. (x[i] - x[j]). Note that Δx and Δy can be positive or negative so do not use Math.abs(). Do not consider changing the universal gravitational constant G to patch your code!

Sound

I can play MP3s using my favorite media player, but no sound plays in Java. What could be wrong? If you are running Windows, be sure that the audio stream that Java uses is not muted via Start -> Programs -> Accessories -> Multimedia -> Volume Control -> Wave Out.

Testing and Debugging

Inserting print statements is a good way to trace what your program is doing. Our input files were created with the following StdOut.printf() statements.

StdOut.printf("%d\n", n);
StdOut.printf("%.2e\n", radius);
for (int i = 0; i < n; i++) {
    StdOut.printf("%11.4e %11.4e %11.4e %11.4e %11.4e %12s\n",
                   px[i], py[i], vx[i], vy[i], mass[i], image[i]);
}

As indicated in the collaboration policy, you may not copy or adapt code (except from the course materials). Moreover, you need to cite any code that you copy or adapt (except for code provided with the assignment). So, you are free to copy or adapt this code fragment, with or without citation.

Here are our results for a few sample inputs.

% java-introcs NBody 0.0 25000.0 < planets.txt           // zero steps
5
2.50e+11
 1.4960e+11  0.0000e+00  0.0000e+00  2.9800e+04  5.9740e+24    earth.gif
 2.2790e+11  0.0000e+00  0.0000e+00  2.4100e+04  6.4190e+23     mars.gif
 5.7900e+10  0.0000e+00  0.0000e+00  4.7900e+04  3.3020e+23  mercury.gif
 0.0000e+00  0.0000e+00  0.0000e+00  0.0000e+00  1.9890e+30      sun.gif
 1.0820e+11  0.0000e+00  0.0000e+00  3.5000e+04  4.8690e+24    venus.gif

% java-introcs NBody 25000.0 25000.0 < planets.txt       // one step
5
2.50e+11
 1.4960e+11  7.4500e+08 -1.4820e+02  2.9800e+04  5.9740e+24    earth.gif
 2.2790e+11  6.0250e+08 -6.3860e+01  2.4100e+04  6.4190e+23     mars.gif
 5.7875e+10  1.1975e+09 -9.8933e+02  4.7900e+04  3.3020e+23  mercury.gif
 3.3087e+01  0.0000e+00  1.3235e-03  0.0000e+00  1.9890e+30      sun.gif
 1.0819e+11  8.7500e+08 -2.8329e+02  3.5000e+04  4.8690e+24    venus.gif

% java-introcs NBody 50000.0 25000.0 < planets.txt       // two steps
5
2.50e+11
 1.4959e+11  1.4900e+09 -2.9640e+02  2.9799e+04  5.9740e+24    earth.gif
 2.2790e+11  1.2050e+09 -1.2772e+02  2.4100e+04  6.4190e+23     mars.gif
 5.7826e+10  2.3945e+09 -1.9789e+03  4.7880e+04  3.3020e+23  mercury.gif
 9.9262e+01  2.8198e-01  2.6470e-03  1.1279e-05  1.9890e+30      sun.gif
 1.0818e+11  1.7499e+09 -5.6660e+02  3.4998e+04  4.8690e+24    venus.gif

% java-introcs NBody 60000.0 25000.0 < planets.txt       // three steps
5
2.50e+11
 1.4958e+11  2.2349e+09 -4.4460e+02  2.9798e+04  5.9740e+24    earth.gif
 2.2789e+11  1.8075e+09 -1.9158e+02  2.4099e+04  6.4190e+23     mars.gif
 5.7752e+10  3.5905e+09 -2.9682e+03  4.7839e+04  3.3020e+23  mercury.gif
 1.9852e+02  1.1280e+00  3.9705e-03  3.3841e-05  1.9890e+30      sun.gif
 1.0816e+11  2.6248e+09 -8.4989e+02  3.4993e+04  4.8690e+24    venus.gif


% java-introcs NBody 31557600.0 25000.0 < planets.txt    // one year
5
2.50e+11
 1.4959e+11 -1.6531e+09  3.2949e+02  2.9798e+04  5.9740e+24    earth.gif
-2.2153e+11 -4.9263e+10  5.1805e+03 -2.3640e+04  6.4190e+23     mars.gif
 3.4771e+10  4.5752e+10 -3.8269e+04  2.9415e+04  3.3020e+23  mercury.gif
 5.9426e+05  6.2357e+06 -5.8569e-02  1.6285e-01  1.9890e+30      sun.gif
-7.3731e+10 -7.9391e+10  2.5433e+04 -2.3973e+04  4.8690e+24    venus.gif

// this test should take only a few seconds. 4.294E9 is bigger than the largest int
% java-introcs NBody 4.294E9 2.147E9 < 3body.txt
3
1.25e+11
 2.1470e+12 -7.8082e-03  5.0000e+02 -3.6368e-12  5.9740e+24    earth.gif
 1.2882e+14 -1.5100e+17  3.0000e+04 -3.5165e+07  1.9890e+30      sun.gif
-1.2882e+14  1.5100e+17 -3.0000e+04  3.5165e+07  1.9890e+30      sun.gif

Possible Progress Steps

These are purely suggestions for how you might make progress. You do not have to follow these steps. If you get stumped or frustrated on some portion of the assignment, you should not hesitate to consult a preceptor.

The key to composing a large program is decomposing it into smaller steps that can be implemented and tested incrementally. Here is the decomposition we recommend for this assignment.

Parse command-line arguments

Read universe from standard input

Initialize standard drawing

Play music on standard audio

Simulate the universe

Calculate net forces

Update velocities and positions

Draw universe to standard drawing

Print universe to standard output

These are the order in which the components will appear in your code. However, to facilitate testing and debugging, we recommend implementing them in the following order.

Step 1: parse command-line arguments

Parse the two command-line arguments Τ and Δt and store their values. Name the first command-line argument tau or stoppingTime since you should not begin a Java variable name with an uppercase letter.
Print the variables to make sure you parsed them correctly (and in the specified order).
```
% java-introcs NBody 157788000.0 25000.0 < planets.txt
T  = 1.57788E8
dt = 25000.0
```

Step 2: read universe from standard input

Review the input format specified on the assignment page. The sample input files planets.txt and 3body.txt conform to this format. Your program should be able to read either of these files, via redirection from standard input.
Read the data from standard input, storing the number of bodies in an integer variable n, the radius of the universe in a floating-point variable radius, and the remaining information in six parallel arrays: Let px[i], py[i], vx[i], vy[i], and mass[i] be floating-point numbers which store the current position (x- and y-coordinates), velocity (x- and y-components), and mass of body i; let image[i] be a string which represents the filename of the image used to display body i.

Step 6: print universe to standard output

Print the universe in the specified format.

Run your program with planets.txt. You should see exactly the output below.

% java-introcs NBody 0.0 25000.0 < planets.txt
5
2.50e+11
 1.4960e+11  0.0000e+00  0.0000e+00  2.9800e+04  5.9740e+24    earth.gif
 2.2790e+11  0.0000e+00  0.0000e+00  2.4100e+04  6.4190e+23     mars.gif
 5.7900e+10  0.0000e+00  0.0000e+00  4.7900e+04  3.3020e+23  mercury.gif
 0.0000e+00  0.0000e+00  0.0000e+00  0.0000e+00  1.9890e+30      sun.gif
 1.0820e+11  0.0000e+00  0.0000e+00  3.5000e+04  4.8690e+24    venus.gif

Test your program on another input file.

% java-introcs NBody 0.0 1.0 < 3body-zero-gravity.txt
3
5.12e+02
 0.0000e+00  0.0000e+00  1.0000e+00  1.0000e+00  1.0000e-30    earth.gif
 1.2800e+02  0.0000e+00  2.0000e+00  1.0000e+00  1.0000e-40    venus.gif
 0.0000e+00  1.2800e+02  1.0000e+00  2.0000e+00  1.0000e-50     mars.gif

Submit your code via TigerFile and click the Check Submitted Files button. If everything is correct so far (reading and printing the universe), your code should pass Tests 1–3. Do not continue to the next step until it does.

Step 3: initialize standard drawing

Set the scale of the standard drawing window so that (0, 0) is at the center, (−radius, −radius) is the lower-left corner, and (+radius, +radius) is the upper-right corner.
Call StdDraw.enableDoubleBuffering() to enable double buffering and support animation.

Step 4: play music on standard audio

Call StdAudio.play("2001.wav") to play the background music.

Step 5: simulate the universe

Create the "time" loop. Its body will perform a single time step of the simulation, starting at t = 0.0, and continuing in Δt increments as long as t < Τ. This code goes between the code where you read the input and the code where you print the output.
Test your program by printing the time t at each time step.

% java-introcs NBody 23.0 2.5 < planets.txt
t = 0.0
t = 2.5
t = 5.0
t = 7.5
t = 10.0
t = 12.5
t = 15.0
t = 17.5
t = 20.0
t = 22.5

% java-introcs NBody 25.0 2.5 < planets.txt
t = 0.0
t = 2.5
t = 5.0
t = 7.5
t = 10.0
t = 12.5
t = 15.0
t = 17.5
t = 20.0
t = 22.5

Once you are confident that your time loop is correct, comment out the code that prints the time t at each time step.
Steps 5C, 5B, and 5A (below) will go inside this time loop.

Step 5B: update the velocities and positions

Write a loop to calculate the new velocity and position for each body. Since you haven't yet incorporated gravity, assume the acceleration acting on each body is zero.

Test on an artificial universe, where it is easy to check the expected results by hand.

% java-introcs NBody 1 1 < 3body-zero-gravity.txt
3
5.12e+02
 1.0000e+00  1.0000e+00  1.0000e+00  1.0000e+00  1.0000e-30    earth.gif
 1.3000e+02  1.0000e+00  2.0000e+00  1.0000e+00  1.0000e-40    venus.gif
 1.0000e+00  1.3000e+02  1.0000e+00  2.0000e+00  1.0000e-50     mars.gif

% java-introcs NBody 192 1 < 3body-zero-gravity.txt
3
5.12e+02
 1.9200e+02  1.9200e+02  1.0000e+00  1.0000e+00  1.0000e-30    earth.gif
 5.1200e+02  1.9200e+02  2.0000e+00  1.0000e+00  1.0000e-40    venus.gif
 1.9200e+02  5.1200e+02  1.0000e+00  2.0000e+00  1.0000e-50     mars.gif

Submit your code via TigerFile and click the Check Submitted Files button. If everything is correct so far (ignoring the gravitational forces and drawing), your code should pass Tests 1–7. Do not continue to the next step until it does.

Step 5C: draw universe to standard drawing

Use StdDraw.picture(x, y, filename) to draw the background image starfield.jpg, centered at (0, 0).
Then, write a loop to display the n bodies. (This code goes after the code from Step 5B.)
Run the program with planets.txt. You should now see the four planets moving off the screen in a straight line, with constant velocity.
```
% java-introcs NBody 157788000.0 25000.0 < planets.txt
```
]

Your browser can not display this movie.
Be sure that Javascript is enabled and that you have Flash 9.0.124 or better.
If the planets are flickering, be sure you are using double buffering, following the template in BouncingBall.java. In particular, call StdDraw.enableDoubleBuffering() once at the beginning of the program; and call StdDraw.show() and StdDraw.pause(20) at the end of each time step (frame), not after each call to StdDraw.picture().
Run your program on another input file, such as kaleidoscope.txt.
```
% java-introcs NBody 157788000.0 25000.0 < kaleidoscope.txt
```
Submit your code via TigerFile and click the Check Submitted Files button. If everything is correct so far (ignoring the gravitational forces), your code should pass Tests 1–13. Do not continue to the next step until it does.

Step 5A: calculate the forces

To calculate the net force acting on each body, use two additional arrays fx[i] and fy[i] to store the net force acting on body i. (This code goes before the code from Step 5B.)
Initialize all the net forces to zero.
Write two nested for loops to calculate the net force exerted by body j on body i. Add these values to fx[i] and fy[i], but skip the case when i equals j.
Once you have these values computed, go back to Step 5B and use them to compute the acceleration (instead of assuming it is zero).
Test your program on several data files.
Submit your code via TigerFile and click the Check Submitted Files button. Your code should now pass all of the tests.

Enrichment

What is the music in 2001.wav? It's the fanfare to Also sprach Zarathustra by Richard Strauss. It was popularized as the key musical motif in Stanley Kubrick's 1968 film 2001: A Space Odyssey.

I'm a physicist. Why should I use the leapfrog method instead of the formula I derived in high school? In other words, why does the position update formula use the velocity at the updated time step rather than the previous one? Why not use the ½ a t² formula? The leapfrog method is more stable for integrating Hamiltonian systems than conventional numerical methods like Euler's method or Runge–Kutta. The leapfrog method is symplectic, which means it preserves properties specific to Hamiltonian systems (conservation of linear and angular momentum, time-reversibility, and conservation of energy of the discrete Hamiltonian). In contrast, ordinary numerical methods become dissipative and exhibit qualitatively different long-term behavior. For example, the earth would slowly spiral into (or away from) the sun. For these reasons, symplectic methods are extremely popular for n-body calculations in practice. You asked!

Here's a more complete explanation of how you should interpret the variables. The classic Euler method updates the position uses the velocity at time t instead of using the updated velocity at time t + Δt. A better idea is to use the velocity at the midpoint t + Δt / 2. The leapfrog method does this in a clever way. It maintains the position and velocity one-half time step out of phase: At the beginning of an iteration, (p_x, p_y) represents the position at time t and (v_x, v_y) represents the velocity at time t − Δt / 2. Interpreting the position and velocity in this way, the updated position (p_x + Δt v_x, p_y + Δt v_y). uses the velocity at time t + Δt / 2. Almost magically, the only special care needed to deal with the half time-steps is to initialize the system's velocity at time t = −Δt / 2 (instead of t = 0.0), and you can assume that we have already done this for you. Note also that the acceleration is computed at time t so that when we update the velocity, we are using the acceleration at the midpoint of the interval under consideration.

Are there analytic solutions known for n-body systems? Yes, Sundman and Wang developed global analytic solutions using convergent power series. However, the series converge so slowly that they are not useful in practice. See The Solution of the N-body Problem for a brief history of the problem.

Who uses n-body simulation? N-body simulations play a crucial role in our understanding of the universe. Astrophysicists use it to study stellar dynamics at the galactic center, stellar dynamics in a globular cluster, colliding galaxies, and the formation of the structure of the Universe. The strongest evidence we have for the belief that there is a black hole in the center of the Milky Way comes from very accurate n-body simulations. Many of the problems that astrophysicists want to solve have millions or billions of particles. More sophisticated computational techniques are needed.

The same methods are also widely used in molecular dynamics, except that the heavenly bodies are replaced by atoms, gravity is replaced by some other force, and the leapfrog method is called Verlet's method. With van der Waals forces, the interaction energy may decay as 1/R ⁶ instead of an inverse square law. Occasionally, 3-way interactions must be taken into account, e.g., to account for the covalent bonds in diamond crystals.

Kepler's Orrery uses an n-body simulator to compose and play music.

What techniques are used to do n-body simulation in practice? Here's a wealth of information on n-body simulation.

Any ideas for creating my own universe? Here are some interesting two-body systems. Here is beautiful 21-body system in a figure-8 —reproducing this system (in a data file in our format) will earn you a small amount extra credit.