Fundamental Counting Principle: Worksheet 6 - Intermediate-Advanced Practice Fundamental Counting Principle INTERMEDIATE ADVANCED

Ready to master Fundamental Counting Principle? This timed practice ⚡ worksheet (6/10) presents 20 intermediate-advanced-level challenges. Focus area: speed building. Learn to solve fundamental counting principle tricks, handle fundamental counting principle shortcut methods, and perfect fundamental counting principle bank exam questions with our step-by-step solutions.

📝 Worksheet 6 of 10 • 20 questions • ⏱️ Estimated time: 20 minutes • 🎯 Intermediate Advanced level

What you'll learn in this worksheet:

Understand the logic behind fundamental counting principle shortcut methods
Learn step-by-step approaches to speed building
Handle multi-step problems systematically
Master complex problem variations and edge cases
Master fundamental counting principle tricks through focused practice

Your progress through Fundamental Counting Principle

Worksheet 6 of 10 (55% complete)

Question 1

A restaurant offers 3 appetizers, 7 main courses, and 4 desserts. How many different meal combinations can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 3 options
- Second choice: 7 options
- Third choice: 4 options

Calculation:
Total ways = 3 × 7 × 4 = 84

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 3 first choices can be paired with each of the 7 second choices (3×7=21), and each of these can be combined with any of the 4 third choices.

Question 2

A car model has 3 colors, 7 engine types, and 5 interior options. How many different different car configurations can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 3 options
- Second choice: 7 options
- Third choice: 5 options

Calculation:
Total ways = 3 × 7 × 5 = 105

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 3 first choices can be paired with each of the 7 second choices (3×7=21), and each of these can be combined with any of the 5 third choices.

Question 3

A restaurant offers 6 appetizers, 4 main courses, and 5 desserts. How many different meal combinations can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 6 options
- Second choice: 4 options
- Third choice: 5 options

Calculation:
Total ways = 6 × 4 × 5 = 120

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 6 first choices can be paired with each of the 4 second choices (6×4=24), and each of these can be combined with any of the 5 third choices.

Question 4

A car model has 3 colors, 4 engine types, and 5 interior options. How many different different car configurations can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 3 options
- Second choice: 4 options
- Third choice: 5 options

Calculation:
Total ways = 3 × 4 × 5 = 60

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 3 first choices can be paired with each of the 4 second choices (3×4=12), and each of these can be combined with any of the 5 third choices.

Question 5

A car model has 5 colors, 5 engine types, and 3 interior options. How many different different car configurations can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 5 options
- Second choice: 5 options
- Third choice: 3 options

Calculation:
Total ways = 5 × 5 × 3 = 75

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 5 first choices can be paired with each of the 5 second choices (5×5=25), and each of these can be combined with any of the 3 third choices.

Question 6

A car model has 4 colors, 7 engine types, and 4 interior options. How many different different car configurations can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 4 options
- Second choice: 7 options
- Third choice: 4 options

Calculation:
Total ways = 4 × 7 × 4 = 112

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 4 first choices can be paired with each of the 7 second choices (4×7=28), and each of these can be combined with any of the 4 third choices.

Question 7

A car model has 4 colors, 4 engine types, and 2 interior options. How many different different car configurations can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 4 options
- Second choice: 4 options
- Third choice: 2 options

Calculation:
Total ways = 4 × 4 × 2 = 32

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 4 first choices can be paired with each of the 4 second choices (4×4=16), and each of these can be combined with any of the 2 third choices.

Question 8

A restaurant offers 5 appetizers, 5 main courses, and 4 desserts. How many different meal combinations can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 5 options
- Second choice: 5 options
- Third choice: 4 options

Calculation:
Total ways = 5 × 5 × 4 = 100

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 5 first choices can be paired with each of the 5 second choices (5×5=25), and each of these can be combined with any of the 4 third choices.

Question 9

A restaurant offers 3 appetizers, 5 main courses, and 2 desserts. How many different meal combinations can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 3 options
- Second choice: 5 options
- Third choice: 2 options

Calculation:
Total ways = 3 × 5 × 2 = 30

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 3 first choices can be paired with each of the 5 second choices (3×5=15), and each of these can be combined with any of the 2 third choices.

Question 10

A car model has 4 colors, 4 engine types, and 3 interior options. How many different different car configurations can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 4 options
- Second choice: 4 options
- Third choice: 3 options

Calculation:
Total ways = 4 × 4 × 3 = 48

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 4 first choices can be paired with each of the 4 second choices (4×4=16), and each of these can be combined with any of the 3 third choices.

Question 11

A student has 6 shirts, 5 pants, and 2 pairs of shoes. How many different outfits can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 6 options
- Second choice: 5 options
- Third choice: 2 options

Calculation:
Total ways = 6 × 5 × 2 = 60

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 6 first choices can be paired with each of the 5 second choices (6×5=30), and each of these can be combined with any of the 2 third choices.

Question 12

A student has 4 shirts, 6 pants, and 5 pairs of shoes. How many different outfits can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 4 options
- Second choice: 6 options
- Third choice: 5 options

Calculation:
Total ways = 4 × 6 × 5 = 120

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 4 first choices can be paired with each of the 6 second choices (4×6=24), and each of these can be combined with any of the 5 third choices.

Question 13

A restaurant offers 6 appetizers, 5 main courses, and 5 desserts. How many different meal combinations can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 6 options
- Second choice: 5 options
- Third choice: 5 options

Calculation:
Total ways = 6 × 5 × 5 = 150

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 6 first choices can be paired with each of the 5 second choices (6×5=30), and each of these can be combined with any of the 5 third choices.

Question 14

A restaurant offers 5 appetizers, 4 main courses, and 2 desserts. How many different meal combinations can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 5 options
- Second choice: 4 options
- Third choice: 2 options

Calculation:
Total ways = 5 × 4 × 2 = 40

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 5 first choices can be paired with each of the 4 second choices (5×4=20), and each of these can be combined with any of the 2 third choices.

Question 15

A restaurant offers 4 appetizers, 7 main courses, and 4 desserts. How many different meal combinations can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 4 options
- Second choice: 7 options
- Third choice: 4 options

Calculation:
Total ways = 4 × 7 × 4 = 112

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 4 first choices can be paired with each of the 7 second choices (4×7=28), and each of these can be combined with any of the 4 third choices.

Question 16

A student has 6 shirts, 7 pants, and 5 pairs of shoes. How many different outfits can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 6 options
- Second choice: 7 options
- Third choice: 5 options

Calculation:
Total ways = 6 × 7 × 5 = 210

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 6 first choices can be paired with each of the 7 second choices (6×7=42), and each of these can be combined with any of the 5 third choices.

Question 17

A car model has 6 colors, 5 engine types, and 3 interior options. How many different different car configurations can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 6 options
- Second choice: 5 options
- Third choice: 3 options

Calculation:
Total ways = 6 × 5 × 3 = 90

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 6 first choices can be paired with each of the 5 second choices (6×5=30), and each of these can be combined with any of the 3 third choices.

Question 18

A restaurant offers 3 appetizers, 7 main courses, and 3 desserts. How many different meal combinations can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 3 options
- Second choice: 7 options
- Third choice: 3 options

Calculation:
Total ways = 3 × 7 × 3 = 63

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 3 first choices can be paired with each of the 7 second choices (3×7=21), and each of these can be combined with any of the 3 third choices.

Question 19

A car model has 4 colors, 4 engine types, and 4 interior options. How many different different car configurations can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 4 options
- Second choice: 4 options
- Third choice: 4 options

Calculation:
Total ways = 4 × 4 × 4 = 64

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 4 first choices can be paired with each of the 4 second choices (4×4=16), and each of these can be combined with any of the 4 third choices.

Question 20

A car model has 6 colors, 5 engine types, and 3 interior options. How many different different car configurations can be made?

Step-by-Step Solution:

Concept: This problem uses the Fundamental Counting Principle (Multiplication Rule). When making sequential independent choices, multiply the number of options at each step.

Analysis:
- First choice: 6 options
- Second choice: 5 options
- Third choice: 3 options

Calculation:
Total ways = 6 × 5 × 3 = 90

Key Principle: For independent sequential events, multiply the number of choices at each stage.

Verification: Each of the 6 first choices can be paired with each of the 5 second choices (6×5=30), and each of these can be combined with any of the 3 third choices.

🏆 Halfway champion! 55% through Fundamental Counting Principle. Keep the momentum!

Previous Worksheet Next Worksheet