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It’s finally summer! You and your family are on a cross-country road trip. You have the radio cranked up, and you’re all singing along to your favorite song. You drive through a tunnel, and the music stops. If you’re listening to a local radio station, the music will turn to static, but if you’re listening to satellite radio, the music will completely go silent. Radio, whether satellite or over the air, is transmitted as a signal that is interpreted by your device. If you’re listening to satellite radio, the signal is digital, but if you’re listening to broadcast or “over the air” radio the signal is analog. In the following activities, we will learn more about the features of digital and analog signals by simulating how these two types of signals are transmitted and used to store information. Analog Vs. Digital SignalsDigital and analog signals are transmitted through electromagnetic waves. Changes in frequency and amplitude create the music you listen to or images that you see on a screen. Analog signals are composed of continuous waves that can have any values for frequency and amplitude. These waves are smooth and curved. Digital signals, on the other hand, are composed of precise values of 1s and 0s. Digital waves have a step-like appearance. Analog signals are prone to distortion because even slight errors in amplitude or frequency of the wave will change the original signal. Digital signals are a more reliable form of transmitting information because an error in the amplitude or frequency value would have to be very large in order to cause a jump to a different value.
These two signal types are used to communicate and send information in many different forms, like radio transmission, text messages, phone calls, streaming videos, and playing video games. They also can be used to store information and data. Data storage is used by large companies like banks to store records. Individuals also use data storage for personal use, like storing files, photos, games scores, and much more. Learn more about the features of data storage in the Science Friday series, File Not Found. In this activity, students will simulate sending analog and digital signals, similar to the child’s game of “telephone,” but in the form of copying a series of drawings. This activity models the key differences between digital and analog signals in their resolution and signal fidelity. Students will perform two simulations: one simulating multiple transmissions of an analog signal, and one simulating multiple transmissions of a digital signal. Analog images are composed of rounded lines to represent that analog waves can have infinite values. Digital images are composed of straight lines that follow the grids on the handout representing how digital signals are composed of quantized values. Materials— Scissors — Tape or glue — A black pen or fine tip marker (students should not be allowed multiple attempts to recreate the image) — Communication Signal Simulation Drawing Pages. — One copy of each of the 5 digital and 5 analog aliens per table (one alien type per human) from the Communication Signal Simulation Drawing Pages Teacher Set Up
Communication Signal Simulation Student DirectionsWe are going to simulate the sharing of a message over time and distance. This activity requires passing a paper from person to person, having each person replicate a drawing on it, then passing it onto the next person at your table. Passing the paper and replicating the drawing simulate the time and space over which signals travel. In the first part of the activity, we’ll simulate analog signals. In the second part, we’ll simulate digital.
Post Activity Questions(Complete after both analog & digital rounds) Unfold your alien drawings and observe the images drawn during the activity. – Compare the original image to the final drawing. Identify and describe the similarities and differences between the two images. – Observe the progression of drawings during the activity. Identify and describe what changed during each drawing. Teacher Note: In the analog simulation round, students will observe how tiny changes (distortions/noise) in each copy of the image (signal) result in significant distortion in the final image after multiple transmissions. Analog And Digital Round ComparisonCompare the images from Round 1 and Round 2 activity. – Which round resulted in a more accurate final drawing? Support your choice with evidence from the activity. Teacher Note: In the digital round simulation, the alien images are composed of straight lines that follow the grids on the handout representing how digital signals are composed of quantized, or a limited number of values. When students compare the images they transmitted via analog and digital “signals,” they will notice that there is little distortion in the digitally-transmitted image even after multiple transmissions, unlike what they observed when they transmitted the image using an analog signal. In this activity, students will familiarize themselves with characteristics of digital and analog signals, and apply their characterization to choosing digital or analog storage for a specific example. Materials— Scissors — Digital & Analog Card Sort — Endangered Bird Song Writing Prompt — Claims-Evidence-Reasoning Rubric Teacher Set Up
Student Directions
Writing PromptWhich type of signal would you suggest to record a highly-detailed song of an endangered bird? Support your choice with evidence from your card sort. Use the Claims-Evidence-Reasoning (CER) Rubric to help guide your writing. Related Educational Resource In this activity, we’ll use binary coding to represent pathways through a series of “high” and “low” choices, which represent which path to take on a logic map. Students will act as digital-analog converters to decode binary pulses, and to create a picture by changing the pulses into colored pixels. The music transmitted to your car via satellite radio and the information stored in data libraries are both digital signals that use a binary system. In a binary system, there are only two digits, 1 and 0. The value or meaning of these digits can vary. For example, they can represent “true” and “false,” “on” and “off,” or “high” and “low.” This graphic shows how binary coding can be used to represent pathways through a series of “high” and “low” choices. Following the binary code will guide the path to take on a logic map, and help in finding the intended colors. A “1” will indicate to take the “high” path and a “0” will indicate the “low” path. With this map, called a “logic gate map”, a binary series of 0’s and 1’s can indicate when to “go high” or “go low”, conveying a path in the map to “code” for a color. For example, using the logic map above, 010 would indicate “0” go down, “1” go up, “0” go down. This will code for the color green. Now You TryUse this chart to determine what color would be coded by the number 111? If you ended at black, you got it! Digital signals are transmitted to computers in the form of electronic signals sent as pulses. The digital device interprets each pulse’s voltage as either a 0 or 1. The image below is an example of a digitized wave. Using this graph, where the red lines on the top part represent a “1”, and the red lines on the bottom part represent a “0”, you can see that the entire red line represents the sequence of 1s and 0s along the top of the graph: 11001110111011. If we were to use each group of three numbers to find a corresponding color on the table above, we would use: 110 – pink Pixels ExplainedMost electronics like smartphones, computers, and television screens use liquid crystal display (LCD) technology. The screen is made of millions of tiny pieces called pixels. The electronic device receives coded information, in the form of digital signals, and uses electricity to control the color of the pixels. Each tiny pixel is simply changing from one color to the next depending on the electrical signal, but since the pixels are so small your eye detects movement in the overall image. An amazing example of this in nature, are the scales or “pixels” on a butterfly wing picture below and in this cool video. How Does The Activity Work?Each student is assigned a digital wave graph like the one pictured below. Using the logic gate map, students will decode the signal into the pixel colors for part of the mosaic. The first digits will be entered in the first cell and the following digits will be filled in order. Then the logic gate map will be used to determine their colors. Credit: Andrea LaRosa Students will complete this table as they decode their colors. In this example, the colors decoded by student #1 are shown in the top left corner. Credit: Andrea LaRosa Each student’s signal will contribute a piece of the total image. Credit: Andrea LaRosaTo make your own classroom mosaic masterpiece, four classes complete a panel of a larger Post-it mural. The mural created by the four classes is an ocean scene. Credit: Andrea LaRosaMaterials— Meter stick — Tape — Legal size paper, cut in half lengthwise for the grid labels — Student logic gate map and student grid tables — Binary sequence graphs — Eight 22×28 inch poster boards (suggest using two per class): — 2 x 2-inch Post-it stickies: — 2 packs Post-it Super Sticky Notes, 2 in x 2 in, Rio de Janeiro Collection — 1 pack Post-it Super Sticky Notes, 2 in x 2 in, Marrakesh Collection — 1 pack Post-it Super Sticky Notes, 2 in x 2 in, Bright Neons — Note to educators: The packs above will make the full mosaic with correct colors (154 Post-it stickies per poster board). If the Post-it stickies are not available, students can color in the grid with markers. PreparationBefore the students create their Post-it masterpiece, draw a 14 by 11 square grid on each poster board. The rows and columns will both be two inches wide (the width of your stickies). Tape the two poster boards together along the 28-inch sides so that you create a 22 x 11 grid. Print out the student binary sequences and grid assignment tables. Cut these sheets along the dotted lines and give each student the assigned sequence and corresponding grid table. Your setup should look like this: Student ProcedureDecode: You will decode 10-12 squares on the grid. Below is an example of a binary sequence graph. The red line is a digital representation of a signal. Use your assigned signal graph and the logic map to decode the binary sequence and color in your grid table. Check your answers with your teacher before moving onto mosaic construction. Construct: Get the number and colors of Post-its for your section of the mosaic. Place your stickies onto the corresponding squares in the poster board grid. Teacher Tip: Create a prelabeled poster board to help your students create the mosaic. Credit: Andrea LaRosaAdd the Post-its to the poster board grid in the correct order. As you do, think of each square on the grid as a pixel, and your color choice as a result of the processing of the binary code to get the right color! — What did your class make? — Do you think you could create a binary code guide to make a mural?
— Signal Simulation and Binary Conversion Reflection — Writing CER Rubric Teacher Set Up
Writing Prompt— Use the following tables to make a claim for which type of signal, digital or analog, is a more reliable way to encode and transmit information. Provide three pieces of evidence to support your claim from your findings from the signal simulation and binary conversion learning activities. Table 1: Signal Simulation
Table 2: Binary Conversion Activity: this data represents the information coded for only 3 students.
MS-PS4-3: Integrate qualitative scientific and technical information to support the claim that digitized signals are a more reliable way to encode and transmit information than analog signals. Coding assistance by Luca Fox LaRosa
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