Understanding Differential Equations with Complex Roots

A times the second derivative plus B times the first derivative plus C times the function equals zero

A times the first derivative plus B times the second derivative plus C times the function equals zero

A times the second derivative plus B times the function plus C times the first derivative equals zero

A times the function plus B times the first derivative plus C times the second derivative equals zero

The roots are complex conjugates

The roots are imaginary and equal

The roots are real and equal

The roots are real and distinct

As lambda divided by mu

As lambda times mu

As lambda plus or minus mu

As lambda plus or minus mu i

y = c1 e^(lambda x) e^(mu i x) + c2 e^(lambda x) e^(-mu i x)

y = c1 e^(lambda x) e^(mu x) + c2 e^(lambda x) e^(-mu x)

y = c1 e^(lambda x) e^(mu i) + c2 e^(lambda x) e^(-mu i)

y = c1 e^(lambda x) + c2 e^(mu x)

e^(i theta) = cos(theta) + i sin(theta)

e^(i theta) = cos(theta) - i sin(theta)

e^(i theta) = sin(theta) + i cos(theta)

e^(i theta) = sin(theta) - i cos(theta)

By converting exponential expressions to trigonometric form

By factoring out real numbers

By eliminating imaginary numbers

By converting trigonometric expressions to exponential form

It relates exponential functions to logarithmic functions

It connects trigonometric functions with exponential functions

It simplifies polynomial equations

It provides a method for solving linear equations

i

1

-1

0

y = c1 e^(lambda x) cos(mu x) + c2 e^(lambda x) sin(mu x)

y = c1 e^(lambda x) sin(mu x) + c2 e^(lambda x) cos(mu x)

y = c1 e^(lambda x) cos(mu x) + c2 e^(lambda x) cos(mu x)

y = c1 e^(lambda x) sin(mu x) + c2 e^(lambda x) sin(mu x)

The roots are real and distinct

The roots are imaginary and equal

The roots are equal

The roots are complex conjugates