Post on 26-Sep-2020
Student BookSERIES
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Chance and Probability
Copyright ©
Contents
Topic 1 – Chance and probability (pp. 1–10)
• probability scale________________________________________
• using samples to predict probability________________________
• tree diagrams__________________________________________
• chance experiments_____________________________________
• using tables_ __________________________________________
• location, location – apply________________________________
• lucky throw – solve_ ____________________________________
Date_completed
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Series G – Chance and Probability
Series Authors:
Rachel Flenley
Nicola Herringer
SERIES TOPIC
1G 1Copyright © 3P Learning
Chance and Probability
Reuben_is_going_to_put_ten_blocks_in_
a_bag_and_ask_a_friend_to_choose_one_
without_looking._Circle_the_blocks_
he_could_put_in_the_bag_to_make_the_
probability_of_choosing_a_cube__2__10 .
What_is_the_probability_of_spinning_a_striped_segment_on_each_of_these_wheels?_Write_your_answer_as__a_rating_between_0_and_1_using_decimals.
Probability_measures_how_likely_something_is_to_happen._Events_that_are_certain_to_happen_are_given__a_probability_of_1._Events_that_will_never_happen_are_given_a_probability_of_0._Events_that_could_happen__are_rated_between_0_and_1.
EventProbability__as_a_fraction
Probability__as_a_decimal
When you flip a coin, it will land on heads.
You will grow wings and fly today.
A spinner with 10 even segments with the numbers 1 to 10 will land on 3.
5 people are lined up and every second person in the line has gloves on. What is the chance that one person is not wearing gloves?
You have 20 cards. 5 have hearts, 5 have stripes and the rest are blank. What is the chance you will choose a blank card?
Chance and probability – probability scale
1
2
3
a b c d
Probability measures how likely something is to happen.
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1
impossible even certain
likelyunlikely
0 10
1 10
2 10
3 10
4 10
5 10
6 10
7 10
8 10
9 10
10 10
SERIES TOPIC
G 12Copyright © 3P Learning
Chance and Probability
Sam_did_an_experiment_with_10_cubes_that_were_either_red,_white_or_blue._She_took_a_cube_from_a_jar_without_looking,_tallied_which_colour_it_was_then_put_it_back_in_the_same_jar._She_repeated_the_process__20_times._After_tallying_her_results,_she_created_this_pie_chart_to_show_the_results_of_the_experiment.
Inside_a_box_there_are_3_rectangles,_2_triangles_and_5_squares.__Without_looking,_Ellie_chooses_one_shape_from_the_box._
a Draw each shape on this probability scale to show the probability of Ellie choosing each type of shape.
b 3 more rectangles, 2 more triangles and 5 more squares are added to the same box. Draw each shape on this probability scale to show the probability of Ellie choosing each shape from the box.
c What do you notice? ___________________________________________________________________
Chance and probability – probability scale
100_guests_each_buy_a_ticket_for_a_raffle_at_a_fundraising_dinner._The_winning_ticket_will_be_selected_at_random._This_table_on_the_right_shows_the_colours_of_all_of_the_tickets_in_the_raffle.
What is the probability of the winning ticket being red, purple or orange? Draw arrows on this probability scale to show the probability of each colour and write the colour beneath the arrow.
4
5
6
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1
a How many times did Sam take each colour out of the jar? Remember she performed the experiment 20 times.
Red
White
Blue
b Draw the combination of cubes there could have been inside the jar. Remember there are only 10 cubes.
WhiteRed
Blue
Red 10
Purple 40
Orange 50
Total 100
SERIES TOPIC
3G 1Copyright © 3P Learning
Chance and Probability
Faisal_has_had_enough_of_selling_clothes._If_one_more_woman_asks_him,_“Do_I_look_fat_in_this?”,_he_will_scream._He_holds_a_crazy_closing_down_sale_and_sells_the_following_items_in_1_hour:
Shirts Jackets Skirts Dresses
18 14 7 3
Predict_how_many:
a jackets would sell in 2 hours b skirts would sell in 2 hours
c shirts would sell in 3 hours d dresses would sell in 4 hours
e shirts and jackets would sell in 4 hours
f items of clothing would sell in 8 hours
Surveys are used to collect data about certain topics or questions. Once the data is collected, it is presented in a table so it is easy to understand. Surveys can be conducted to ask all kinds of questions.
We can use probability to see an even bigger picture than the survey tells us.This table shows the data collected when 50 people were surveyed to find their favourite milkshake flavour.
Chocolate Strawberry Vanilla Banana
19 16 8 7
We can use probability to predict the number of people who will choose each flavour in a larger survey.When 100 people are surveyed, it is likely that chocolate will be the favourite milkshake flavour of 38 people.When 1000 people are surveyed, it is likely that chocolate will be the favourite milkshake flavour of 380 people.
Chance and probability – using samples to predict probability
1
Here_is_a_table_showing_the_results_from_a_survey_of_50_boys_and_50_girls_who_were_asked,_“Which_fruit_do_you_like_best?”_Rate_the_probability_that_a_person_selected_randomly_will_be:
a a boy
b a girl who likes apples
c someone who likes pears
d Is the probability of someone choosing a banana greater than or less than 12 ? ____________________
2
Girls Boys
Apple 17 11
Banana 8 14
Orange 13 16
Pear 12 9
SERIES TOPIC
G 14Copyright © 3P Learning
Chance and Probability
When_customers_buy_a_new_car_from_Joe’s_Motors_they_can_pay_an_additional_cost_for_each_of_these_optional_extras:_
• Alloy_wheels_instead_of_standard_wheels_ • Metallic_paint_instead_of_standard_paint
• Automatic_transmission_instead_of__ • Leather_seats_instead_of_standard_seatsmanual_transmission
a Complete this tree diagram to work out all the possible combinations that customers can choose:
Chance and probability – tree diagrams
1
Automatic transmission
Manual transmission
Tree diagrams are used to display all possible outcomes in a simple chance experiment. Here is an example:Matilda’s father is making her lunch and has given her the following choice:white or brown bread, lettuce or sprouts, tuna or egg. We can then follow each branch along to see the different options.
sandwich
white bread
brown bread
sprouts
sprouts
lettuce
lettuce
tuna
egg
tuna
egg
tuna
egg
tuna
egg
By using a tree diagram,
we can see that Matilda
has 8 different options for
her sandwich.
b How many possible combinations are there? ________________________________________________
SERIES TOPIC
5G 1Copyright © 3P Learning
Chance and Probability
Chance and probability – tree diagrams
You_have_an_after_school_job_at_the_local_ice-cream_shop._Your_boss_has_asked_you_to_run_a_special_on__the_strawberry_and_banana_ice-cream_flavours_as_she_mistakenly_ordered_far_too_much_of_each.
You_decide_to_offer_a_double_scoop_special_–_customers_can_choose_2_scoops_and_a_topping_for_the_price_of_a_single_scoop_cone._As_all_ice-cream_connoisseurs_know,_it_matters_which_flavour_goes_on_top_so_customers_may_choose_a_strawberry-banana_combo,_a_banana-strawberry_combo_or_2_scoops_of_the_same_flavour.
Work_out_the_different_combinations_customers_could_order_if_they_could_choose_from_2_cone_types,__the_2_flavours_and_2_different_toppings._Decide_which_cones_and_toppings_you_will_offer.
2
3 Think_about_this:
a How many different combinations are there in total?
b If a customer hates banana ice-cream flavour, how many options do they have?
c What would be your pick?
SERIES TOPIC
G 16Copyright © 3P Learning
Chance and Probability
What_is_the_probability_of_landing_on:
a a yellow b blue and 1
c a 4 d yellow and 3
If_you_did_this_60_times,_how_many_times_would_you_expect_to_get:
a blue and 4 b a red
c a 1 d a 5
Chance and probability – chance experiments
Complete_the_tree_diagram_to_show_all_the_possible_outcomes_when_you_spin_Spinner_1_and_then_Spinner_2._The_first_one_is_done_for_you.
1
2
3
1
2
3blue
4
5
Spinner_1
Spinner_2
yellowblue
red
1
54
2
3
There_were_15_possible_outcomes_in_Question_1._60_is_4_×_15,_so_I_would_expect_each_number_to_be__4_times_greater.
SERIES TOPIC
7G 1Copyright © 3P Learning
Chance and Probability
Now_try_this_experiment._You_will_work_with_a_partner_and_roll_2_dice_36_times._First_make_your_predictions_as_to_how_often_you_will_roll_each_answer._Write_this_in_the_first_row._This_is_the______________probability._Now_actually_roll_two_die_36_times._In_the_bottom_row,_tally_the_number_of_times_each_total_appears._This_is_the__________________probability.
Total 2 3 4 5 6 7 8 9 10 11 12
Number of times you expect to see each total
Number of times you actually get each total
Chance and probability – using tables
1
2
3
4
When_we_roll_2_dice_together,_we_can_get_a_number_of_totals._Fill_in_this_table_to_show_the_possible_outcomes_when_2_regular_dice_are_rolled_and_added_together:
Die_1
Die_2
+ 1 2 3 4 5 6
1
2
3
4
5
6
a How many different ways can the dice be rolled?
b Which total occurred the most often? Shade this in the grid.
c Which totals occurred the least often? Circle these on the grid.
When we work out all the possible outcomes of an event that could happen, we are finding out the theoretical probability. When we do the experiment and look at the probability of what actually happened, we call it experimental probability.
Theoretical probability is: number of favourable outcomestotal number of possible outcomes
Experimental probability is:number of times the event occurred total number of trials
Graph_the_outcomes_from_the_table_above_in_the_grid_below.__Express_the_theoretical_probability_of_the_following_as_a_fraction:
Num
ber_of_outcomes
2 3 4 5 6 7 8 9 10 11 12Possible_totals
Look_at_the_difference_between_the_two_rows._Is_this_what_you_expected?
b 9 =
d 10 =
a 7 =
c 2 =
SERIES TOPIC
G 18Copyright © 3P Learning
Chance and Probability
Make_up_your_own_crazy_set_of_dice._Show_the_sample_in_the_space_on_the_left_and_show_what_they_look_like_on_the_two_nets_of_cubes_on_the_right.
Look_at_the_next_table_for_the_sample_space_of_a_set_of_dice.
_ a Complete the rest of the table to show the sample space.
_ b Show what one die looks like on this net of a cube.
_
_ c What is the chance of rolling:
2 yellows?
2 dots?
Cover_2_dice_with_white_stickers_so_that_the_sides_are_covered_on_each_die._Colour_4_of_the_faces_yellow_and_colour_2_faces_red:_ a Complete the table to show the sample space.
_ b What are the chances of rolling 2 yellows?Colour the table to show this.
_ c What are the chances of rolling 1 yellow and 1 red?
_
d What are the chances of rolling 2 reds?
Now we are going to investigate the sample space of when the dice are different to regular dice. For this you will need 2 regular dice and some white stickers to stick over the sides of the dice.
Chance and probability – using tables
5
6
7
Die_1
Die_2
+ Y Y Y Y R R
Y YY
Y
Y YR
Y
R RY
R
Die_1
Die_2
+ Y Y G G l l
Y YY YY YG YG Yl Yl
Y YY YY YG YG Yl Yl
G GY GY GG GG Gl Yl
G GY GY GG GG Yl Yl
l
l
Die_1
Die_2
+Die_1
Die_2
SERIES TOPIC
9G 1Copyright © 3P Learning
Chance and Probability
Location, location apply
Play this game with a friend. You will need one copy of this game board, a counter each and two dice.
Place your counter in the start hexagon. Take turns rolling both dice and adding the numbers.
• If your answer is a 2, 3 or 4 move one space towards the striped hexagons.
• If your answer is a 5, 6, 7, 8 or 9 move one space towards the dotted hexagons.
• If your answer is a 10, 11 or 12 move one space towards the checked hexagons.
When your counter gets to a hexagon on the edge, record your points and start again.
Play 5 games. Who is the grand winner?
Why are the points allocated as they are? Why does it matter what your dice roll is? Explain your reasoning to a friend.
Getting_ready
What_to_do
What_to_do_next
WIN_10_
points
WIN_10_
points
START
WIN_5_
points
WIN_5_
pointsWIN_2_
points
WIN_80_
points
WIN_60_
points
WIN_40_
points
WIN_20_
points
WIN_80_
points
WIN_60_
points
WIN_20_
points
WIN_40_
points
SERIES TOPIC
G 110Copyright © 3P Learning
Chance and Probability
Lucky throw solve
This is a version of a very old game, played by children all over the world. You will need 40 counters, 2 playing pieces (you could use erasers or chess pieces) 3 pop sticks and a partner.
Decorate 1 side only of each of the pop sticks. Arrange the counters in a circle like this:
Place your playing pieces on opposite sides of the circle and mark your starting point.The aim of the game is to be the first person to move around the circle and get back to your starting point.
Take turns throwing the 3 pop sticks up and looking at the result. The number of counters you can move depends on your combination of decorated and undecorated pop sticks:
• 3 decorated sides = move 10 counters
• 3 plain sides = move 5 counters
• 2 decorated sides and 1 plain side = move 3 counters
• 1 decorated side and 2 plain sides = move 1 counter
If the other player lands on you, you must return to your starting point. The first person back to the Start wins.
After you finish the game, make a tree diagram of all the possible throw outcomes. Use the diagram to answer the following questions:
• What is the likelihood of throwing 3 decorated sides?
• What is the likelihood of throwing 3 plain sides?
• What is the likelihood of throwing 2 decorated and 1 plain sides?
• What is the likelihood of throwing 1 decorated and 2 plain sides?
Based on this, do you think the scoring system is fair? How would you change the scoring system to make it fairer? Play the game again with your new scoring system. Does this improve the game? Or do you prefer the original game? Why?
Getting_ready
What_to_do
What_to_do_next
START
START