1 Introduction.- 2 Review of Ordinary Differential Equations.- 2.1 First Order Linear Differential Equations.- 2.2 Second and Higher Order Linear Differential Equations.- 2.3 Higher Order Linear Differential Equations with Constant Coefficients.- 2.6 Conclusion.- 3 Review of Difference Equations.- 3.1 Introduction.- 3.2 First Order Difference Equations.- 3.3 Second Order Linear Difference Equations.- 3.4 Higher Order Difference Equations.- 3.5 Stability Conditions.- 3.6 Economic Applications.- 3.7 Concluding Remarks.- 4 Review of Some Linear Algebra.- 4.1 Vector and Vector Spaces.- 4.2 Matrices.- 4.3 Determinant Functions.- 4.4 Matrix Inversion and Applications.- 4.5 Eigenvalues and Eigenvectors.- 4.6 Quadratic Forms.- 4.7 Diagonalization of Matrices.- 4.8 Jordan Canonical Form.- 4.9 Idempotent Matrices and Projection.- 4.10 Conclusion.- 5 First Order Differential Equations Systems.- 5.1 Introduction.- 5.2 Constant Coefficient Linear Differential Equation (ODE) Systems.- 5.3 Jordan Canonical Form of ODE Systems.- 5.4 Alternative Methods for Solving ? = Ax.- 5.5 Reduction to First Order of ODE Systems.- 5.6 Fundamental Matrix.- 5.7 Stability Conditions of ODE Systems.- 5.8 Qualitative Solution: Phase Portrait Diagrams.- 5.9 Some Economic Applications.- 6 First Order Difference Equations Systems.- 6.1 First Order Linear Systems.- 6.2 Jordan Canonical Form.- 6.3 Reduction to First Order Systems.- 6.4 Stability Conditions.- 6.5 Qualitative Solutions: Phase Diagrams.- 6.6 Some Economic Applications.- 7 Nonlinear Systems.- 7.1 Introduction.- 7.2 Linearization Theory.- 7.3 Qualitative Solution: Phase Diagrams.- 7.4 Limit Cycles.- 7.5 The Liénard-Van der Pol Equations and the Uniqueness of Limit Cycles.- 7.6 Linear and Nonlinear Maps.- 7.7 Stability of Dynamical Systems.-7.8 Conclusion.- 8 Gradient Systems, Lagrangean and Hamiltonian Systems.- 8.1 Introduction.- 8.2 The Gradient Dynamic Systems (GDS).- 8.3 Lagrangean and Hamiltonian Systems.- 8.4 Hamiltonian Dynamics.- 8.5 Economic Applications.- 8.6 Conclusion.- 9 Simplifying Dynamical Systems.- 9.1 Introduction.- 9.2 Poincaré Map.- 9.3 Floquet Theory.- 9.4 Centre Manifold Theorem (CMT).- 9.5 Normal Forms.- 9.6 Elimination of Passive Coordinates.- 9.7 Liapunov-Schmidt Reduction.- 9.8 Economic Applications and Conclusions.- 10 Bifurcation, Chaos and Catastrophes in Dynamical Systems.- 10.1 Introduction.- 10.2 Bifurcation Theory (BT).- 10.3 Chaotic or Complex Dynamical Systems (DS).- 10.4 Catastrophe Theory (C.T.).- 10.5 Concluding Remarks.- 11 Optimal Dynamical Systems.- 11.1 Introduction.- 11.2 Pontryagin's Maximum Principle.- 11.3 Stabilization Control Models.- 11.4 Some Economic Applications.- 11.5 Asymptotic Stability of Optimal Dynamical Systems (ODS).- 11.6 Structural Stability of Optimal Dynamical Systems.- 11.7 Conclusion.- 12 Some Applications in Economics and Biology.- 12.1 Introduction.- 12.2 Economic Applications of Dynamical Systems.- 2.1. Flexible Multiplier-Accelerator Models.- 2.2. Kaldor's Type of Flexible Accelerator Models.- 2.3. Goodwin's Class Struggle Model.- 2.1. Two Sector Models.- 2.2. Economic Growth with Money.- 2.3. Optimal Economic Growth Models.- 2.4. Endogenous Economic Growth Models.- 12.3 Dynamical Systems in Biology.- 12.4 Bioeconomics and Natural Resources.- 12.5 Conclusion.