Skip to content Skip to navigation

Connexions

You are here: Home » Content » Continuous Random Variables: Lab I

Navigation

Content Actions
  • Download module PDF
  • Add to ...
    Add the module to:
    • My Favorites
    • A lens
    • An external social bookmarking service
    • My Favorites (What is 'My Favorites'?)
      'My Favorites' is a special kind of lens which you can use to bookmark modules and collections directly in Connexions. 'My Favorites' can only be seen by you, and collections saved in 'My Favorites' can remember the last module you were on. You need a Connexions account to use 'My Favorites'.
    • A lens (What is a lens?)

      Definition of a lens

      Lenses

      A lens is a custom view of Connexions content. You can think of it as a fancy kind of list that will let you see Connexions through the eyes of organizations and people you trust.

      What is in a lens?

      Lens makers point to Connexions materials (modules and collections), creating a guide that includes their own comments and descriptive tags about the content.

      Who can create a lens?

      Any individual Connexions member, a community, or a respected organization.

    • External bookmarks
  • E-mail the authors

Lenses

What is a lens?

Definition of a lens

Lenses

A lens is a custom view of Connexions content. You can think of it as a fancy kind of list that will let you see Connexions through the eyes of organizations and people you trust.

What is in a lens?

Lens makers point to Connexions materials (modules and collections), creating a guide that includes their own comments and descriptive tags about the content.

Who can create a lens?

Any individual Connexions member, a community, or a respected organization.

This content is ...

In these lenses

  • Printable Books

    This module is included inLens: Connexions Books Available for Print on Demand
    By: ConnexionsAs a part of collection:"Collaborative Statistics"

    Comments:

    "This book was purchased from the authors by the Maxfield Foundation and provided to the community as an open textbook available freely online and in PDF format. Bound copies of the book can also […]"

    Click the "Printable Books" link to see all content selected in this lens.

  • Bio 502 at CSUDH

    This module is included inLens: Bio 502
    By: Terrence McGlynnAs a part of collection:"Collaborative Statistics"

    Comments:

    "This is the course textbook for Biology 502 at CSU Dominguez Hills"

    Click the "Bio 502 at CSUDH" link to see all content selected in this lens.

Recently Viewed

Tags

(What is a tag?)

These tags come from the endorsement, affiliation, and other lenses that include this content.

Continuous Random Variables: Lab I

Module by: Dr. Barbara Illowsky, Susan Dean

Summary: In this lab exercise, students will compare and contrast empirical data from a random number generator with the Uniform Distribution.

Class Time:

Names:

Student Learning Outcomes:

  • The student will compare and contrast empirical data from a random number generator with the Uniform Distribution.

Collect the Data

Use a random number generator to generate 50 values between 0 and 1 (inclusive). List them below. Round the numbers to 4 decimal places or set the calculator MODE to 4 places.

  1. Complete the table:
    __________ __________ __________ __________ __________
    __________ __________ __________ __________ __________
    __________ __________ __________ __________ __________
    __________ __________ __________ __________ __________
    __________ __________ __________ __________ __________
    __________ __________ __________ __________ __________
    __________ __________ __________ __________ __________
    __________ __________ __________ __________ __________
    __________ __________ __________ __________ __________
    __________ __________ __________ __________ __________
  2. Calculate the following:
    • a. x¯=x¯= size 12{ {overline {x}} ={}} {}
    • b. s=s= size 12{s={}} {}
    • c. 40th percentile =
    • d. 3rd quartile =
    • e. Median =

Organizing the Data

  1. Construct a histogram of the empirical data. Make 8 bars.
    Figure 1
    Blank graph with relative frequency on the vertical axis and X on the horizontal axis.
  2. Construct a histogram of the empirical data. Make 5 bars.
    Figure 2
    Blank graph with relative frequency on the vertical axis and X on the horizontal axis.

Describe the Data

  1. Describe the shape of each graph. Use 2 – 3 complete sentences. (Keep it simple. Does the graph go straight across, does it have a V shape, does it have a hump in the middle or at either end, etc.? One way to help you determine a shape, is to roughly draw a smooth curve through the top of the bars.)
  2. Describe how changing the number of bars might change the shape.

Theoretical Distribution

  1. In words, X X =
  2. The theoretical distribution of XX is XX ~ U(0,1)U(0,1). Use it for this part.
  3. In theory, based upon the distribution in the section titled "Organizing the Data",
    • a. μ = μ=
    • b. σ = σ=
    • c. 40th percentile =
    • d. 3rd quartile =
    • e. median = __________
  4. Are the empirical values (the data) in the section titled "Collect the Data" close to the corresponding theoretical values above? Why or why not?

Plot the Data

  1. Construct a box plot of the data. Be sure to use a ruler to scale accurately and draw straight edges.
  2. Do you notice any potential outliers? If so, which values are they? Either way, numerically justify your answer. (Recall that any DATA are less than Q1 – 1.5*IQR or more than Q3 + 1.5*IQR are potential outliers. IQR means interquartile range.)

Comparing the Data

  1. For each part below, use a complete sentence to comment on how the value obtained from the data compares to the theoretical value you expected from the distribution in the section titled "Theoretical Data".
    • a. minimum value:
    • b. first quartile:
    • c. median:
    • d. third quartile:
    • e. maximum value:
    • f. width of IQR:
    • g. overall shape:
  2. Based on your comments in the section titled "Collect the Data", how does the box plot fit or not fit what you would expect of the distribution in the section titled "Theoretical Distribution"?

Discussion Question

  1. Suppose that the number of values generated was 500, not 50. How would that affect what you would expect the empirical data to be and the shape of its graph to look like?

Comments, questions, feedback, criticisms?

Send feedback