The video is a discussion about the strength and durability of two versions of Batman: DC Batman from The Dark Knight trilogy and Lego Batman from the Lego movie series. The host, using principles of physics and real-world data, calculates the strength of both Batmans in terms of their ability to exert force and take damage.
The host first measures the strength of Lego Batman by calculating the force exerted when he kicks Alfred (a minifigure) across a room. Using the principles of motion, the host determines that Lego Batman's kick is delivering 754.34 centimeters per second squared, or 7.5434 meters per second squared, which equates to a strength-to-weight ratio of 0.769.
Next, the host calculates the strength of Christian Bale's Batman by examining a scene where Batman shatters some bricks with a kick. Using the force recorded when astronaut Ronald McNair broke some bricks with a kick (675 pounds of force), the host determines that Batman's strength-to-weight ratio is 3.214 over four times.
The host then measures the durability of both Batmans by calculating the force exerted when they are hit by a car. The host determines that Lego Batman's body can withstand a force of 19,900 pounds, while Christian Bale's body can withstand a force of 159 pounds.
Finally, the host calculates the strength of Lego Batman when he is building with Legos. Using data from a report on the strength required to build with Legos, the host determines that Lego Batman's strength-to-weight ratio skyrockets to 790.148, equivalent to Christian Bale exerting 158,000 pounds of force.
In conclusion, the host determines that Lego Batman, despite being a small figure, is surprisingly strong and durable, even surpassing Christian Bale's Batman in terms of strength-to-weight ratio. The host also discusses the importance of creativity and problem-solving in the Lego universe, suggesting that these skills contribute to Lego Batman's strength.
1. The video is about comparing the strength of two versions of Batman: the fictional Lego Batman and the real-life Batman, Christian Bale.
2. The video uses the movie "The Dark Knight" trilogy as a reference for the real-life Batman.
3. The video uses the Lego movie and its sequel as references for the fictional Lego Batman.
4. The video uses the concept of force and mass to calculate the strength of the characters.
5. The video uses the concept of strength to weight ratio to compare the strength of the characters.
6. The video uses the concept of acceleration to calculate the strength of the characters.
7. The video uses the concept of durability to compare the strength of the characters.
8. The video uses the concept of creativity and problem-solving to calculate the strength of the characters.
9. The video uses the concept of super strength to calculate the strength of the characters.
10. The video uses the concept of strength required to build with Legos to calculate the strength of the characters.
11. The video uses the concept of the strength required to separate Lego bricks to calculate the strength of the characters.
12. The video uses the concept of the strength required to lift an adult male African bush elephant to calculate the strength of the characters.
13. The video uses the concept of the strength required to lift 11 more adult male African bush elephants to calculate the strength of the characters.
14. The video uses the concept of the strength required to lift an adult male African bush elephant and 11 more adult male African bush elephants to calculate the strength of the characters.
15. The video uses the concept of the strength required to lift an adult male African bush elephant, 11 more adult male African bush elephants, and a 10-pound dumbbell to calculate the strength of the characters.
16. The video uses the concept of the strength required to lift an adult male African bush elephant, 11 more adult male African bush elephants, a 10-pound dumbbell, and a piano to calculate the strength of the characters.
17. The video uses the concept of the strength required to lift an adult male African bush elephant, 11 more adult male African bush elephants, a 10-pound dumbbell, a piano, and a 3-gram Lego minifigure to calculate the strength of the characters.
18. The video uses the concept of the strength required to lift an adult male African bush elephant, 11 more adult male African bush elephants, a 10-pound dumbbell, a piano, a 3-gram Lego minifigure, and a 200-pound man to calculate the strength of the characters.
19. The video uses the concept of the strength required to lift an adult male African bush elephant, 11 more adult male African bush elephants, a 10-pound dumbbell, a piano, a 3-gram Lego minifigure, a 200-pound man, and a 159-pound man to calculate the strength of the characters.
20. The video uses the concept of the strength required to lift an adult male African bush elephant, 11 more adult male African bush elephants, a 10-pound dumbbell, a piano, a 3-gram Lego minifigure, a 200-pound man, a 159-pound man, and a 1,580,000-pound man to calculate the strength of the characters.
21. The video uses the concept of the strength required to lift an adult male African bush elephant, 11 more adult male African bush elephants, a 10-pound dumbbell, a piano, a 3-gram Lego minifigure, a 200-pound man, a 159-pound man, a 1,580,000-pound man, and a 15,800,000-pound man to calculate the strength of the characters.
22. The video uses the concept of the strength required to lift an adult male African bush elephant, 11 more adult male African bush elephants, a 10-pound dumbbell, a piano, a 3-gram Lego minifigure, a 20