Chapter 6: Systems of Linear Differential. be continuous functions on the interval

Chapter 6: Systems of Linear Differential Equations Let a (t), a 2 (t),..., a nn (t), b (t), b 2 (t),..., b n (t) be continuous functions on the interval I. The system of n first-order differential equations

x = a (t)x + a 2 (t)x 2 + + a n (t)x n + b (t) x 2 = a 2(t)x + a 22 (t)x 2 + + a 2n (t)x n + b 2 (t).. x n = a n (t)x + a n2 (t)x 2 + + a nn (t)x n + b n (t) is called a first-order linear differential system. The system is homogeneous if b (t) b 2 (t) b n (t) 0 on I. It is nonhomogeneous if the functions b i (t) are not all identically zero on I. 2

Set A(t) = a (t) a 2 (t) a 2 (t) a 22 (t)... a n (t) a n2 (t) a n (t) a 2n (t) a nn (t) and x = x x 2. x n, b(t) = b (t) b 2 (t). b n (t). The system can be written in the vector-matrix form x = A(t)x + b(t). (S) 3

The matrix A(t) is called the matrix of coefficients or the coefficient matrix. The vector b(t) is called the nonhomogeneous term, or forcing function. 4

A solution of the linear differential system (S) is a differentiable vector function x(t) = x (t) x 2 (t). x n (t) that satisfies (S) on the interval I. 5

Example : x = x + 2x 2 5e 2t x 2 = 3x + 2x 2 + 3e 2t Vector/matrix form x x 2 = 2 3 2 x x 2 + 5e2t 3e 2t or x = 2 3 2 x + 5e2t 3e 2t 6

Claim: x(t) = x = e 2t 2 e 2t 2 3 2 is a solution of x + 5e2t 3e 2t 7

x(t) = C 2e4t 3e 4t +C 2 e t e t + e 2t 2 e 2t is a solution for any numbers C, C 2. 8

Example 2: x = 3x x 2 x 3 x 2 = 2x + 3x 2 + 2x 3 x 3 = 4x x 2 2x 3 Vector/matrix form x x 2 x 3 = 3 2 3 2 4 2 x x 2 x 3 or x = 3 2 3 2 4 2 x 9

x(t) = e 3t e 3t e 3t = e3t is a solution. 0

x(t) = C e 3t +C 2 e 2t 0 +C 3 e t 3 7 is a solution for any numbers C, C 2, C 3

THEOREM: The initial-value problem x = A(t)x + b(t), x(t 0 ) = c has a unique solution x = x(t). 2

A linear equation can be written as a system Consider the second order equation y + p(t)y + q(t)y = f(t) Solve for y y = q(t)y p(t)y + f(t) 3

Introduce new dependent variables x, x 2, as follows: x = y x 2 = x (= y ) 4

Vector-matrix form: x x 2 = 0 q p x x 2 + 0 f Note that this system is just a very special case of the general system of two, first-order differential equations: x = a (t)x + a 2 (t)x 2 + b (t) x 2 = a 2(t)x + a 22 (t)x 2 + b 2 (t) 5

Vector-matrix form: x x 2 = a (t) a 2 (t) a 2 (t) a 22 (t) x x 2 + b (t) b 2 (t) or x = A(t)x + b

Example 3: y 5y + 6y = 4e 4t Fundamental set: Particular solution General solution: 6

The equation in system form is: x x 2 = 0 6 5 x x 2 + 0 4e 4t y = e 2t +2e 4t is a soln. of equation Corresponding solution of system???? 7

Consider the third-order equation y + p(t)y + q(t)y + r(t)y = f(t) or y = r(t)y q(t)y p(t)y + f(t). 8

Introduce new dependent variables x, x 2, x 3, as follows: x = y x 2 = x (= y ) x 3 = x 2 (= y ) Then y = x 3 = r(t)x q(t)x 2 p(t)x 3 +f(t) The third-order equation can be written equivalently as the system of three first-order equations: 9

x = x 2 x 2 = x 3 x 3 = r(t)x q(t)x 2 p(t)x 3 + f(t). That is x = 0x + x 2 + 0x 3 x 2 = 0x + 0x 2 + x 3 x 3 = r(t)x q(t)x 2 p(t)x 3 + f(t). 20

Vector-matrix form: x x 2 x 3 = 0 0 0 0 r q p x x 2 x 3 + 0 0 f 2

Note that this system is just a very special case of the general system of three, firstorder differential equations: x = a (t)x + a 2 (t)x 2 + a 3 (t)x 3 (t) + b (t) x 2 = a 2(t)x + a 22 (t)x 2 + a 23 (t)x 3 (t) + b 2 (t) x 3 = a 3(t)x + a 32 (t)x 2 + a 33 (t)x 3 (t) + b 3 (t). or in vector-matrix form: x = A(t)x + b 22

Example 4: y 3y 4y + 2y = 6e t. which can be written y = 2y + 4y + 3y + 6e t. Set x = y x 2 = x (= y ) x 3 = x 2 (= y ) Then x 3 = 2x +4x 2 +3x 3 +6e t 23

Equivalent system: x = x 2 x 2 = x 3 x 3 = 2x + 4x 2 + 3x 3 + 6e t. Which is x = 0x + x 2 + 0x 3 x 2 = 0x + 0x 2 + x 3 x 3 = 2x + 4x 2 + 3x 3 + 6e t. 24

Vector-matrix form: x x 2 x 3 = 0 0 0 0 2 4 3 x x 2 x 3 + 0 0 6e t or x = Ax + b

y 3y 4y + 2y = 6e t Fundamental set: Particular solution General solution 25

y = e 3t + 2 e t is a solution of the equation. System: x x 2 x 3 Recall: x = = y y y 0 0 0 0 2 4 3 x x 2 x 3 = = e 3t 3e 3t 9e 3t y y y x x 2 x 3 + + 2 e t 2 e t 2 e t 0 0 6e t is a corresponding solution of the system. 26

II. Homogeneous Systems: General Theory: x = a (t)x + a 2 (t)x 2 + + a n (t)x n (t) x 2 = a 2(t)x + a 22 (t)x 2 + + a 2n (t)x n (t). x n = a n(t)x + a n2 (t)x 2 + + a nn (t)x n (t). x = A(t)x. (H) Note: The zero vector z(t) 0 = 0 is a solution of (H). This solution is called the trivial 0. 0 solution. 27

THEOREM: If v and v 2 are solutions of (H), then u = v + v 2 is also a solutions of (H); the sum of any two solutions of (H) is a solution of (H). THEOREM: If v is a solution of (H) and α is any real number, then u = αv is also a solution of (H); any constant multiple of a solution of (H) is a solution of (H). 28

In general, THEOREM: If v, v 2,..., v k are solutions of (H), and if c, c 2,..., c k are real numbers, then c v + c 2 v 2 + + c k v k is a solution of (H); any linear combination of solutions of (H) is also a solution of (H). 29

Linear Dependence/Independence in general Let v (t) = v v 2. v n, v 2 (t) = v 2 v 22. v n2,..., v k (t) = v k v 2ḳ. v nk be vector functions defined on some interval I. 30

The vectors are linearly dependent on I if there exist k real numbers c, c 2,..., c k, not all zero, such that c v (t)+c 2 v 2 (t)+ +c k v k (t) 0 on I. Otherwise the vectors are linearly independent on I. 3

THEOREM Let v (t), v 2 (t),..., v k (t) be k, k-component vector functions defined on an interval I. If the vectors are linearly dependent, then v v 2 v k v 2 v 22... v 2k. v k v k2 v kk 0 on I. 32

The determinant v v 2 v k v 2 v 22... v 2k. v k v k2 v kk is called the Wronskian of the vector functions v, v 2,..., v k. 33

Special case: n solutions of (H) THEOREM Let v, v 2,..., v n be n solutions of (H). Exactly one of the following holds:. W(v, v 2,..., v n )(t) 0 on I and the solutions are linearly dependent. 2. W(v, v 2,..., v n )(t) 0 for all t I and the solutions are linearly independent. 34

THEOREM Let v, v 2,..., v n be n linearly independent solutions of (H). Let u be any solution of (H). Then there exists a unique set of constants c, c 2,..., c n such that u = c v + c 2 v 2 + + c n v n. That is, every solution of (H) can be written as a unique linear combination of v, v 2,..., v n. 35

A set of n linearly independent solutions of (H) is called a fundamental set of solutions. A fundamental set is also called a solution basis for (H). The matrix whose columns are v,v 2,...,v n is called a fundamental matrix. 36

Let v, v 2,..., v n be a fundamental set of solutions of (H). Then x = c v + c 2 v 2 + + c n v n, c, c 2,..., c n arbitrary constants, is the general solution of (H). 37

Example Equation: y 5y + 6y = 0 Fundamental set: { y = e 2t, y 2 = e 3t} Equivalent system: x = x 2 x 2 = 6x + 5x 2 38

Vector-matrix form: x x 2 = 0 6 5 x x 2 Solutions: 39

x = e2t 2e 2t, x 2 = e3t 3e 3t is a fundamental set of solutions of the system x x 2 = 0 6 5 x x 2 The matrix X(t) = e2t e 3t 2e 2t 3e 3t is the fundamental matrix. 40

Example 2 y 3y 4y + 2y = 0 Fundamental set: { y = e 3t, y 2 = e 2t, y 3 = e 2t} Equivalent vector-matrix system: x x 2 x 3 Solutions: = 0 0 0 0 2 4 3 x x 2 x 3 4

x = e 3t 3e 3t 9e 3t, x 2 = e 2t 2e 2t 4e 2t x 3 = e 2t 2e 2t 4e 2t is a fundamental set of solutions of the corresponding system x x 2 x 3 = 0 0 0 0 2 4 3 x x 2 x 3 42

and X(t) = e 3t e 2t e 2t 3e 3t 2e 2t 2e 2t 9e 3t 4e 2t 4e 2t is the fundamental matrix. 43

III. Homogeneous Systems with Constant Coefficients x = a x + a 2 x 2 + + a n x n x 2 = a 2x + a 22 x 2 + + a 2n x n.. x n = a nx + a n2 x 2 + + a nn x n where a, a 2,..., a nn are constants. 44

The system in vector-matrix form is x x 2 x n = a a 2 a n a 2 a 22 a 2n a n a n2 a nn x x 2 x n or x = Ax. 45

Solutions of x = Ax: Example x = e2t 2e 2t = e 2t 2 is a solution of What is 2 x = 0 6 5 x relative to 0 6 5? 0 6 5 2 = 46

NOTE: y 5y + 6y = 0 Characteristic equation r 2 5r + 6 = (r 2)(r 3) = 0 Characteristic roots: r = 2, r 2 = 3 Fundamental set: { y = e 2t, y 2 = e 3t} 47

Vector-matrix system x x 2 = 0 6 5 x x 2 A = 0 6 5 Characteristic equation: det(a λi) = λ 6 5 λ = λ 2 5λ + 6 = (λ 2)(λ 3) = 0 Eigenvalues: λ = 2, λ 2 = 3 Fund set: x = e 2t 2,x 2 = e 3t 3 48

Example 2 x = e 3t 3e 3t 9e 3t = e3t 3 9 is a solution of x x 2 x 3 = 0 0 0 0 2 4 3 x x 2 x 3 What is 3 9 relative to 0 0 0 0 2 4 3? 49

0 0 0 0 2 4 3 3 9 = 50

THAT IS: 3 is an eigenvalue of A and v = 3 9 is a corresponding eigenvector. 5

NOTE: y 3y 4y + 2 = 0 Characteristic equation r 3 3r 2 4r 2 = (r 3)(r 2)(r+2) = 0 Characteristic roots: r = 3, r 2 = 3, r 3 = 2 Fundamental set: { y = e 3t, y 2 = e 2t, y 3 = e 2t} 52

Vector-matrix system x x 2 x 3 = 0 0 0 0 2 4 3 x x 2 x 3 A = 0 0 0 0 2 4 3 Characteristic equation: det(a λi) = λ 0 0 λ 2 4 3 λ = λ 3 3λ 2 4λ + 2 = (λ 3)(λ 2)(λ + 2) = 0 53

Eigenvalues: λ = 3, λ 2 = 2, λ 3 = 2 Fund set: x = e 3t x 2 = e 2t x 3 = e 2t 2 4, 2 4 3 9, 54

Given the homogeneous system with constant coefficients x = Ax. CONJECTURE: If λ is an eigenvalue of A and v is a corresponding eigenvector, then x = e λt v is a solution. 55

Proof: Let λ be an eigenvalue of A with corresponding eigenvector v. Set x = e λt v 56

If λ, λ 2,, λ k are distinct eigenvalues of A with corresponding eigenvectors v, v 2,, v k, then x = e λ t v, x 2 = e λ 2t v 2,,x k = e λ kt v k are linearly independent solutions of x = Ax. 57

In particular: If λ, λ 2,, λ n are distinct eigenvalues of A with corresponding eigenvectors v, v 2,, v n, then x = e λ t v, x 2 = e λ 2t v 2,,x n = e λ kt v n forms a fundamental set of solutions of x = Ax. and x = C x +C 2 x 2 + +C n x n is the general solution. 58

. Find the general solution of x = 4 2 x. Step. Find the eigenvalues of A: det(a λi) = 4 λ 2 λ = λ 2 5λ + 6. Characteristic equation: λ 2 5λ + 6 = (λ 2)(λ 3) = 0. Eigenvalues: λ = 2, λ 2 = 3. 59

Step 2. Find the eigenvectors: A λi = 4 λ 2 λ 60

λ = 2, v = 2 ; λ 2 = 3, v 2 =. Solutions: Fundamental set of solution vectors: x = e 2t 2, x 2 = e 3t General solution of the system: x = C e 2t 2 + C 2 e 3t. 6

2. Solve x = 3 2 0 5 4 2 x. Step. Find the eigenvalues of A: det(a λi) = 3 λ 2 λ 5 4 2 λ = λ 3 + 2λ 2 + λ 2. Characteristic equation: λ 3 2λ 2 λ+2 = (λ 2)(λ )(λ+) = 0. Eigenvalues: λ = 2, λ 2 =, λ 3 =. 62

Step 2. Find the eigenvectors: A λi = 3 λ 2 λ 5 4 2 λ λ = 2: 63

λ = 2 : v = 2, λ 2 = : v 2 = 3 7, λ 3 = : v 3 = 2 2. Fundamental set of solutions: x = e 2t 2, x 3 = e t x 2 = e t 2 2. 3 7, 64

Fundamental matrix: X(t) = e 2t 3e t e t e 2t e t 2e t 2e 2t 7e t 2e t The general solution of the system: x = C e 2t 2 +C 2 e t 3 7 +C 3 e t 2 2. 65

3. Solve the initial-value problem x = 3 2 0 5 4 2 x, x(0) = 0. To find the solution vector satisfying the initial condition, solve C v (0)+C 2 v 2 (0)+C 3 v 3 (0) = 0 which is: C 2 +C 2 3 7 +C 3 2 2 = 0 66

or 3 2 2 7 2 C C 2 C 3 = 0. Note: 3 2 2 7 2 = X(0) X(t) the fundamental matrix. Augmented matrix: 3 2 0 2 7 2 67

Solution: C = 3, C 2 =, C 3 =. The solution of the initial-value problem is: x = 3e 2t 2 e t 3 7 +e t 2 2. 68

TWO DIFFICULTIES: I. A has complex eigenvalues and complex eigenvectors. II. A has an eigenvalue of multiplicity greater than. 69

I. Complex eigenvalues/eigenvectors Examples:. Find the general solution of x = 3 2 4 x. det(a λi) = 3 λ 2 4 λ = λ2 +2λ+5. The eigenvalues are: λ = + 2i, λ 2 = 2i. 70

A λi = 3 λ 2 4 λ For λ = + 2i: Solve 2 2i 2 0 4 2 2i 0 7

The solution set is: x 2 = ( + i)x, x arbitrary Set x =. Then, for λ = +2i: v = i = +i 0. and, for λ 2 = 2i: v 2 = i 0. 72

Solutions u = e λ t v = e ( +2i)t [( ) + i ( 0 )] = e t (cos 2t + i sin 2t) [( ) + i ( 0 )] = e t [cos 2t ( ) sin 2t ( 0 )] + i e t [cos 2t ( 0 ) + sin 2t ( )]. 73

u 2 = e λ 2t v 2 = e ( 2i)t [( ) i ( 0 )] = e t (cos 2t + i sin 2t) [( ) + i ( 0 )] = e t [cos 2t ( ) sin 2t ( 0 )] i e t [cos 2t ( 0 ) + sin 2t ( )]. 74

Fundamental set: x = u + u 2 2 = e t cos 2t sin 2t 0 x 2 = u + u 2 2i = e t cos 2t 0 + sin 2t General solution: x = C e t cos 2t sin 2t 0 + C 2 e t cos 2t 0 + sin 2t 75

Summary: x = Ax, A n n const. a+ib, a ib complex eigenvalues. α +i β, α i β corresponding eigenvectors. Independent (complex-valued) solutions: u = e (a+ib)t ( α +i β ) u 2 = e (a ib)t ( α i β ) 76

Corresponding real-valued solutions: x = e at [cos bt α sin bt β ] x 2 = e [cos at bt β +sin bt ] α General solution: x = C e at [cos bt α sin bt β ] + C 2 e [cos at bt β +sin bt ] α 77

2. Determine a fundamental set of solution vectors of x = 4 3 2 3 3 x. det(a λi) = λ 4 3 2 λ 3 3 λ = λ 3 +6λ 2 2λ+26 = (λ 2)(λ 2 4λ+3). The eigenvalues are: λ = 2, λ 2 = 2 + 3i, λ 3 = 2 3i. 78

A λi = λ 4 3 2 λ 3 3 λ λ = 2: Solve 4 0 3 0 3 0 0 v = 0. 79

A λi = λ 4 3 2 λ 3 3 λ For λ 2 = 2 + 3i: Solve 3i 4 0 3 3i 3 0 3i 0 80

The solution set is: x = ( 52 + 32 i ) x 3, x 2 = ( 3 2 + 3 ) 2 i x 3,, x 3 arbitrary. v 2 = 5 + 3i 3 + 3i 2 = 5 3 2 +i 3 3 0. and v 3 = 5 3i 3 3i 2 = 5 3 2 i 3 3 0. 8

Now u = e (2+3i)t 5 3 2 + i 3 3 0 and u 2 = e (2 3i)t 5 3 2 i 3 3 0 convert to: x = e 2t cos 3t 5 3 2 sin 3t 3 3 0 and x 2 = e 2t cos 3t 3 3 0 + sin 3t 5 3 2 82

Fundamental set of solution vectors: x 2 = e 2t x 3 = e 2t x = e 2t cos 3t cos 3t 5 3 2 3 3 0 0, sin 3t + sin 3t 3 3 0 5 3 2,. General solution: x = C x + C 2 x 2 + C 3 x 3 83

II. Repeated eigenvalues Examples:. Find a fundamental set of solutions of x = 3 3 3 5 3 6 6 4 x. det(a λi) = λ 3 3 3 5 λ 3 6 6 4 λ = 6+2λ λ 3 = (λ 4)(λ+2) 2. Eigenvalues: λ = 4, λ 2 = λ 3 = 2 84

λ = 4 : (A 4I) = 3 3 3 3 9 3 3 6 0 85

λ 2 = λ 3 = 2: A ( 2)I = 3 3 3 3 3 3 6 6 6 86

which row reduces to Solution set: 0 0 0 0 0 0 0 0 0. x = a b, x 2 = a, x 3 = b a, b any real numbers. Set a =, b = 0 : v 2 = 0 ; Set a = 0, b = : v 3 = 0. 87

Fundamental set: e 4t 2, e 2t 0, e 2t 0. 88

2. Find a fundamental set of solutions of x = 5 6 2 0 8 0 2 x. det(a λi) = 5 λ 6 2 0 λ 8 0 2 λ = 36+5λ+2λ 2 λ 3 = (λ+4)(λ 3) 2. Eigenvalues: λ = 4, λ 2 = λ 3 = 3. 89

λ = 4 : v = 6 8 3. A ( 4)I = 9 6 2 0 3 8 0 2 90

λ 2 = λ 3 = 3: Solve A 3I = 2 6 2 0 4 8 0 5 9

2 6 2 0 0 4 8 0 0 5 0 which row reduces to 0 5 0 0 2 0 0 0 0 0. x = 5x 3, x 2 = 2x 3, x 3 arbitrary Set x 3 = : v 2 = 5 2 Problem: Only one eigenvector! 92

Solutions: x = e 4t 6 8 3, x 2 = e 3t 5 2. We need a third solution x 3 which is independent of x, x 2. 93

3. y + y 8y 2y = 0 Char.eqn. r 3 +r 2 8r 2 = (r 3)(r+2) 2 = 0. Fundamental set: { e 3t, e 2t, te 2t} 94

Equivalent system: x = det(a λi) = λ 0 0 λ 2 8 λ 0 0 0 0 2 8 = λ 3 λ 2 + 8λ + 2λ x char. eqn.: λ 3 + λ 2 8λ 2 = (λ 3)(λ + 2) 2 Eigenvalues: λ = 3, λ 2 = λ 3 = 2 95

Fundamental set: x = e 3t 3 9, x 2 = e 2t 2 4, x 3 = e 2t 0 4 + te 2t 2 4 Question: What is the vector? 0 4 96

[A ( 2)I] 0 4 = 2 0 0 2 2 8 0 4 = 97

A ( 2I) maps the eigenvector 2 4. 0 4 onto 0 4 is called a generalized eigenvector. 98

2. continued. Solve (A 3I)w = 2 6 2 5 0 4 8 2 0 5 5 2 99

0 5 0 2 /2 0 0 0 0. Solution set: x = +5x 3, x 2 = 2 2x 3, x 3 arbitrary Set x 3 = 0: w = /2 0 00

Fundamental set: x = e 4t 6 8 3, x 2 = e 3t 5 2, x 3 = e 3t /2 0 + te 3t 5 2 0

Eigenvalues of multiplicity 2: Given x = Ax. Suppose that A has an eigenvalue λ of multiplicity 2. Then exactly one of the following holds: 02

. λ has two linearly independent eigenvectors, v and v 2. Corresponding linearly independent solution vectors of the differential system are x (t) = e λt v and x 2 (t) = e λt v 2. (See Example.) 03

2. λ has only one (independent) eigenvector v. (See Examples 2 and 3.) Then a linearly independent pair of solution vectors is: x (t) = e λt v and x 2 (t) = e λt w+te λt v where w is a vector that satisfies (A λi)w = v. The vector w is called a generalized eigenvector corresponding to the eigenvalue λ. 04

Examples:. Find a fundamental set of solutions and the general solution of x = 2 5 4 x. det (A λ I) = 2 λ 5 4 λ = λ 2 6λ + 3 Eigenvalues: 3 + 2i, 3 2i 05

(A λ I) = 2 λ 5 4 λ λ = 3 + 2i, v = + i 2 0 06

Fundamental set: x = e 3t cos 2t sin 2t 2 0 x 2 = e 3t cos 2t 2 0 sin 2t General solution: x(t) = C x + C 2 x 2 07

2. Find a fundamental set of solutions and the general solution of x = 4 2 2 3 2 2 0 x. HINT: 3 is an eigenvalue and 2 is an eigenvalue of multiplicity 2 Characteristic eqn: (λ+3)(λ+2) 2 =0 08

(A λi) = 4 λ 2 2 3 λ 2 2 λ λ = 3 : 09

(A λi) = 4 λ 2 2 3 λ 2 2 λ λ 2 = λ 3 = 2 : 2 0, 0 2 0

Fundamental set: e 3t, e 2t 2 0, e 2t 0 2 General solution: x = C e 3t +C 2 e 2t 2 0 +C 3 e 2t 0 2

3. Find a fundamental set of solutions and the general solution of x = 3 7 5 6 6 2 x. HINT: 4 is an eigenvalue and 2 is an eigenvalue of multiplicity 2 Characteristic eqn: (λ 4)(λ+2) 2 =0 2

(A λi) = 3 λ 7 5 λ 6 6 2 λ λ = 4 : v = 0 3

(A λi) = 3 λ 7 5 λ 6 6 2 λ λ 2 = λ 3 = 2 : v 2 = 0 4

(A λi) = 3 λ 7 5 λ 6 6 2 λ [A ( 2)I]w = 0 5

Fund. Set: e 4t 0, e 2t 0 e 2t + te 2t 0 General solution: x = C e 4t 0 + C 2 e 2t 0 + C 3 e 2t + te 2t 0 6

Eigenvalues of Multiplicity 3. Given the differential system x = Ax. Suppose that λ is an eigenvalue of A of multiplicity 3. Then exactly one of the following holds: 7

. λ has three linearly independent eigenvectors v, v 2, v 3. Then three linearly independent solution vectors of the system corresponding to λ are: x (t) = e λt v, x 2 (t) = e λt v 2, x 3 (t) = e λt v 3. 8

2. λ has two linearly independent eigenvectors v, v 2. Then three linearly independent solutions of the system corresponding to λ are: x (t) = e λt v, x 2 (t) = e λt v 2 and x 3 (t) = e λt w + te λt v where v is an eigenvector corresponding to λ and (A λi)w = v. That is: (A λi) 2 w = 0. 9

3. λ has only one (independent) eigenvector v. Then three linearly independent solutions of the system have the form: x = e λt v, x 2 = e λt w + te λt v, v 3 (t) = e λt z + te λt w + t 2 e λt v where (A λi)z = w & (A λi)w = v, i.e. (A λi) 3 z = 0 & (A λi) 2 w = 0 20

Example: y 6y + 2y 8y = 0 Char. eqn.: (r 2) 3 = 0 Char. roots: r = r 2 = r 3 = 2 Fundamental set: { e 2t, te 2t, t 2 e 2t} 2

Corresponding system: x = 0 0 0 0 8 2 6 x Fundamental set: e 2t 2 4, e 2t 0 4 + te 2t 2 4, e 2t 0 0 2 + te 2t 0 2 8 + t 2 e 2t 2 4 22