For linear multi-input multi-output uncertain systems with external unknown disturbances, this thesis proposed a dynamic output feedback integral sliding mode control method to stabilize the system and suppress the effect of mismatched disturbances. The advantages of sliding mode control are its simple design procedure, great robustness against matched disturbances, etc. As part of system states or outputs are only measurable, conventional output feedback sliding mode controllers involved a synthesis problem by a structural constraint and ensured the approaching and sliding condition locally. The thesis adopted an integral sliding surface to improve the controller synthesis problem, reserved inherent benefits of sliding mode control, and offered an extra degree of freedom to suppress the effect of mismatched disturbances when the system is in the sliding mode, simultaneously. For satisfying the approaching and sliding condition globally, an adaption law was added in the controller to estimate the bound of part of unknown terms. The proposed control method can be modified to apply to uncertain time-delay systems with disturbances. For state delays with a fixed and unknown delay time, combined the output feedback integral sliding mode technique with a full-order compensator can complete the dynamic controller design. Since the system is in the sliding mode, using the property of robust disturbance attenuation can derive a linear matrix inequality as a sufficient condition for the stability; this linear matrix inequality can be decomposed into two smaller algebraic Riccati inequalities by modifying the structure of compensator. Solutions to two types of inequalities can both determine parameters of sliding surface, compensator, and controller. In the case of time-varying and unknown delay time, some delay times caused the instability of system and worsened the difficulty designing the controller. The proposed structure of dynamic sliding mode control can also complete the stability analysis and control law design for systems with time-varying delay.