COS 126Conditionals, Loops, Arrays |
Programming Assignmentchecklist |

The goal of this assignment is to write five short Java programs
to gain practice with loops, conditionals, and arrays.

The goal of this assignment is to write five short Java programs
to gain practice with loops and conditionals.

**Bits.**Write a program`Bits.java`that takes an integer command-line argument`n`and uses a`while`loop to compute the number of times you need to divide`n`by 2 until it is strictly less than 1. Print the error message "`Illegal input`" if`n`is negative.%

**java Bits 0**%**java Bits 8**0 4 %**java Bits 1**%**java Bits 16**1 5 %**java Bits 2**%**java Bits 1000**2 10 %**java Bits 4**%**java Bits -23**3 Illegal input*This computes the number of bits in the binary representation of**n*, which also equals 1 + floor(log_{2}*n*) when*n*is positive. This quantity arises in information theory and the analysis of algorithms.**Boolean and integer variables.**Write a program`Ordered.java`that takes three integer command-line arguments,*x*,*y*, and*z*. Define a`boolean`variable whose value is`true`if the three values are either in strictly ascending order (*x < y < z*) or in strictly descending order (*x > y > z*), and`false`otherwise.

Do%

**java Ordered 10 17 49**true %**java Ordered 49 17 10**true %**java Ordered 10 49 17**false*not*use a conditional or loop (such as an`if`,`while`, or`for`statement) on this question.-
**Type conversion and conditionals.**Several different formats are used to represent color. For example, the primary format for LCD displays, digital cameras, and web pages—known as the*RGB format*—specifies the level of red (R), green (G), and blue (B) on an integer scale from 0 to 255. The primary format for publishing books and magazines—known as the*CMYK format*—specifies the level of cyan (C), magenta (M), yellow (Y), and black (K) on a real scale from 0.0 to 1.0.Write a program

`RGBtoCMYK.java`that converts from RGB format to CMYK format. Your program should take three integer command-line arugments`red`,`green`, and`blue`; print the RGB values; then print the equivalent CMYK values using these mathematical formulas:\( \begin{align*} white \;&=\; \max \left \{ \, \frac{red}{255}, \, \frac{green}{255}, \, \frac{blue}{255} \, \right \} \\ cyan \;&=\; \Bigl(white - \frac{red}{255} \Bigr) \; \div \; white \\ magenta \;&=\; \Bigl(white-\frac{green}{255}\Bigr) \; \div \; white \\ yellow \;&=\; \Bigl(white-\frac{blue}{255}\Bigr) \; \div \; white \\ black \;&=\; 1 - white \end{align*} \)

*Hint.*`Math.max(x, y)`returns the maximum of`x`and`y`.%

**java RGBtoCMYK 75 0 130**// indigo red = 75 green = 0 blue = 130 cyan = 0.423076923076923 magenta = 1.0 yellow = 0.0 black = 0.4901960784313726%

**java RGBtoCMYK 255 143 0**// Princeton orange red = 255 green = 143 blue = 0 cyan = 0.0 magenta = 0.4392156862745098 yellow = 1.0 black = 0.0If the red, green, and blue values are each 0, the resulting color is black. Here is what your program should do:

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**java RGBtoCMYK 0 0 0**// black red = 0 green = 0 blue = 0 cyan = 0.0 magenta = 0.0 yellow = 0.0 black = 1.0 -
**Noon snooze.**Write a program`NoonSnooze.java`that takes an integer command-line argument`snooze`and prints the time of day (using a 12-hour clock) that is`snooze`minutes after 12:00pm (noon).%

**java NoonSnooze 50**12:50pm %**java NoonSnooze 100**1:40pm %**java NoonSnooze 720**12:00am %**java NoonSnooze 11111**5:11am*Note*: you may assume that`snooze`is a non-negative integer.*Hint*: use the integer division and remainder operators. -
**Checkerboard.**Write a program`Checkerboard.java`that takes an integer command-line argument*n*, and uses a nested`for`loop to print an*n*-by-*n*checkerboard pattern like the one below: a total of*n*^{2}asterisks, where each row has 2*n*characters (alternating between asterisks and spaces).%

**java Checkerboard 4**%**java Checkerboard 5*** * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * **A drone's flight.**A drone begins flying aimlessly, starting at Nassau Hall. At each time step, the drone flies one meter in a random direction, either north, east, south, or west, with probability 25%. How far will the drone be from Nassau Hall after*n*steps? This process is known as a two-dimensional*random walk*.-
Write a program
`RandomWalker.java`that takes an integer command-line argument`n`and simulates the motion of a random walk for`n`steps. Print the location at each step (including the starting point), treating the starting point as the origin (0, 0). Also, print the*square*of the final Euclidean distance from the origin.%

**java RandomWalker 10**%**java RandomWalker 20**(0, 0) (0, 0) (0, -1) (0, 1) (0, 0) (-1, 1) (0, 1) (-1, 2) (0, 2) (0, 2) (-1, 2) (1, 2) (-2, 2) (1, 3) (-2, 1) (0, 3) (-1, 1) (-1, 3) (-2, 1) (-2, 3) (-3, 1) (-3, 3) squared distance = 10 (-3, 2) (-4, 2) (-4, 1) (-3, 1) (-3, 0) (-4, 0) (-4, -1) (-3, -1) (-3, -2) (-3, -3) squared distance = 18 -
Write a program
`RandomWalkers.java`that takes two integer command-line arguments`n`and`trials`. In each of`trials`independent experiments, simulate a random walk of`n`steps and compute the squared distance. Output the*mean squared distance*(the average of the`trials`squared distances).%

**java RandomWalkers 100 10000**%**java RandomWalkers 400 2000**mean squared distance = 101.446 mean squared distance = 383.12 %**java RandomWalkers 100 10000**%**java RandomWalkers 800 5000**mean squared distance = 99.1674 mean squared distance = 811.8264 %**java RandomWalkers 200 1000**%**java RandomWalkers 1600 100000**mean squared distance = 195.75 mean squared distance = 1600.13064As

`n`increases, we expect the random walk to end up farther and farther away from the origin. But how much farther? Use`RandomWalkers`to formulate a hypothesis as to how the mean squared distance grows as a function of`n`. Use`trials`= 100,000 to get a sufficiently accurate estimate.

*This process is a discrete version of a natural phenomenon known as Brownian motion. It serves as a scientific model for an astonishing range of physical processes from the dispersion of ink flowing in water, to the formation of polymer chains in chemistry, to cascades of neurons firing in the brain.*-
Write a program
**Dice and the Gaussian distribution.**Write a program`RollDice.java`that takes an integer command-line argument`n`, and rolls 10 fair six-sided dice,`n`times. Use an integer array to tabulate the number of times each possible total (between 10 and 60) occurs. Then print a text histogram of the results, as illustrated below.%

**java RollDice 1000**10: 11: 12: 13: 14: 15: 16: 17: 18: * 19: **** 20: 21: *** 22: ****** 23: ******** 24: **************** 25: ************* 26: ********** 27: ********************************* 28: **************************************** 29: ********************************* 30: *************************************************** 31: ***************************************************************** 32: ******************************************************** 33: ************************************************************************************** 34: *********************************************************** 35: ********************************************************************* 36: *********************************************************************************** 37: ************************************************************** 38: ***************************************************************** 39: *************************************** 40: ***************************************************** 41: ************************************ 42: **************************** 43: ************************ 44: ************************ 45: ********* 46: *********** 47: ******* 48: *** 49: ** 50: 51: 52: * 53: 54: 55: 56: 57: 58: 59: 60:*Note*: you should assume that`n`is a non-negative integer.*The central limit theorem, a key result in probability and statistics, asserts that the shape of the resulting histogram tends to the ubiquitous bell curve (Gaussian distribution) if the number of dice and rolls is large.*

**Program style and format.**
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**Submission.**
Submit the files
`Bits.java`,
`NoonSnooze.java`,
`Ordered.java`,
`RGBtoCMYK.java`,
`Checkerboard.java`,
`RandomWalker.java`,
`RandomWalkers.java`,
`RollDice.java`,
and
a completed readme.txt file.

**Challenge for the bored.**
Implement `NoonSnooze.java` without using any `if` statements;
also, handle negative snooze times.