1.1: Basic Drive Commands

Welcome to your first lesson with Zumi! 🎉 Before you begin machine learning with Zumi, she needs help from you to learn how to go forward, reverse, left, and right.
zumi_beginner zumi_beginner

This lesson works with:

Zumi
Python
  • basic
  • beginner
  • drive commands
  • programming
  • Python
  • Zumi

Grade level:

6 - 12+

Approx. time required:

60 - 75 mins
CSTA

2-AP-10

6-8

Use flowcharts and/or pseudocode to address complex problems as algorithms.

2-AP-16

6-8

Incorporate existing code, media, and libraries into original programs, and give attribution.

3B-AP-16

11-12

Demonstrate code reuse by creating programming solutions using libraries and APIs.
CCSS

CCSS.ELA-Literacy.RST.11-12.3 Language Arts

Grades 11, 12

Follow precisely a complex multistep procedure when carrying out experiments, taking measurements, or performing technical tasks; analyze the specific results based on explanations in the text.

Read More

CCSS.ELA-LITERACY.RST.6-8.3 Language Arts

6-8

Follow precisely a multistep procedure when carrying out experiments, taking measurements, or performing technical tasks. 

CCSS.ELA-LITERACY.RST.9-10.3 Language Arts

Grade 9-10

Follow precisely a complex multistep procedure when carrying out experiments, taking measurements, or performing technical tasks, attending to special cases or exceptions defined in the text.

CCSS.Math.Practice.MP1 Math

High School — Geometry

Make sense of problems and persevere in solving them.

Read More

CCSS.Math.Practice.MP5 Math

Grade 3

Use appropriate tools strategically.

Read More

CCSS.Math.Practice.MP7 Math

Grade 5

Look for and make use of structure.

Read More
NGSS

HS-PS2-1 Science

Grades 9, 10, 11, 12

Analyze data to support the claim that Newton's second law of motion describes the mathematical relationship among the net force on a macroscopic object, its mass, and its acceleration.

MS-ETS1-1 Science

Grades 6, 7, 8

Define the criteria and constraints of a design problem with sufficient precision to ensure a successful solution, taking into account relevant scientific principles and potential impacts on people and the natural environment that may limit possible solutions.

MS-ETS1-2 Science

Grades 6, 7, 8

Evaluate competing design solutions using a systematic process to determine how well they meet the criteria and constraints of the problem.

MS-PS2-2 Science

Grades 6, 7, 8

Plan an investigation to provide evidence that the change in an object's motion depends on the sum of the forces on the object and the mass of the object.
Step 1

Import libraries

The first step to running any code with Zumi will be to import libraries. In other words, this cell imports all of Zumi’s necessary features, like the drive commands, camera, or screen. If you don’t run this cell, the rest of your program won’t work! You only need to run the following cell once in each lesson, unless you restart the Jupyter Notebook.

In [ ]:

from zumi.zumi import Zumi
import time

zumi = Zumi()

 

Degrees

The code below will have Zumi turn right 45 degrees instead of 90:

 

In [ ]:

zumi.turn_right(45)

 

Since Zumi is turning 120 degrees, you should increase the duration or Zumi will not be able to finish. You may need to adjust the second parameter because each Zumi is unique. Use the cell below to experiment driving and making turns.

In [ ]:

# Test some code here

Recalibrating

In [ ]:

zumi.mpu.calibrate_MPU()

In [ ]:

# Write some more code here!
Step 2

Drive Commands

Zumi uses functions to drive. In this lesson, we will go more in-depth with what functions are, what they do, and how you can use them to create your remote control.

Step 3

What are functions?

To make Zumi drive, we need to use some functions. Think of functions as packages of code that you can use to make your program more efficient. They can take inputs and can have outputs.

Step 4

Zumi Functions

Below is a list of the basic drive functions:

  • forward(): Drive forward in the direction Zumi is facing at speed 40 for 1 second
  • reverse(): Reverse in the direction Zumi is facing at speed 40 for 1 second
  • turn_left(): Pivot 90 degrees to the left
  • turn_right(): Pivot 90 degrees to the right
Step 5

How to call functions

In computer science, calling anything is basically asking it to run. Functions must be called using the object name, which in this case is zumi.

The cell below has an example using the forward() function. Zumi will drive forward for one second, so make sure you have enough space in its area!

In []:

zumi.forward()

Now try going in reverse!

Let’s go over the next two functions. Calling turn_left() and turn_right() will cause Zumi to turn to the left or turn to the right.

Test this code below and then add more commands in any order to see what happens. If you want to have some time between each command, include a time.sleep(seconds) to delay the program for the specified number of seconds. Run the code below to see how this works, and then try adding some more commands to the code.

In []:

zumi.forward() # Drive forward for 1 second then stop
time.sleep(2) # Wait 2 seconds
zumi.turn_right() # Turn right 90 degrees
# Add more code here!
Step 6

Parameters

At this point, you may want to change the duration, direction, and speed that Zumi drives forward. Some functions will allow you to input parameters, which are extra pieces of information that allow you to further customize your function for your needs. Right now forward() has a default speed, duration, and direction, but you can alter the parameters to change how fast Zumi drives, as well as for how long in a certain direction.

We’re going to skip changing Zumi’s direction since it requires some more understanding of Zumi’s sensors, but you can change the speed and duration by defining them inside of the function call. In the cell below, the code has been modified to reduce the speed to 30 and drive for 2 seconds. Make sure you have enough space!

In[]:

zumi.forward(speed=30, duration=2)

You can do the same for reverse. Change the speed and duration for reverse().

Step 7

Degrees

The functions turn_left() and turn_right() also have parameters you can change. The default value is set to 90 degrees, but that value can be changed as well.

The code below will have Zumi turn right 45 degrees instead of 90:

In []:

zumi.turn_right(45)

Try out the accuracy of the turns by testing different angles. Use this diagram for reference if you need it! Zumi isn’t perfect, so the actual angle that Zumi stops at might be off by one or two degrees.

Note: There is another hidden default parameter in turn_right() and turn_left(). When you call turn_left(45), you are actually calling turn_left(desired_angle=45, duration=1). The duration is what determines how much time Zumi has to complete that turn. One second is enough time for smaller turns, but what if you wanted to turn 135 degrees? You will also have to increase the time that Zumi needs to make the turn.

zumi.turn_left(120, 1.5)

Since Zumi is turning 120 degrees, you should increase the duration or Zumi will not be able to finish. You may need to adjust the second parameter because each Zumi is unique. Take some time to experiment driving and making turns.

Step 8

Recalibrating

If you find that Zumi isn’t going straight, you may need to recalibrate. This may happen if Zumi starts to overheat. Make sure you aren’t picking up Zumi and she is resting on a flat surface.

zumi.mpu.calibrate_MPU()

Now you know the basics! Test out some more code. For an added challenge, use some materials around you to build a simple obstacle course and write some code for Zumi to go through it without hitting anything. In the next lesson, you will learn how to combine the drive commands with if statements to make your own remote control.

Step 9

Extension Activities

Bridge Challenge

Build a bridge out of the object of your choice. However, this object should be flat and relatively wide so Zumi’s wheels don’t get stuck. Popsicle sticks will work well. Constraints like the degree of incline, height, width, and number of popsicle sticks can be used. After building the bridge, see if a) Zumi is able to cross it and/or b) if the bridge can support Zumi’s weight. For an extra challenge, a payload can be added to Zumi.

Calculate Speed

Drive your Zumi for a certain distance or time while measuring the other. Next, use the equation d=rt to find the rate of travel. Afterwards, graph your results either and analyze the results. To incorporate physics, add a payload to Zumi. How does this affect Zumi’s rate?

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