The replication of the human sense of touch in robots or prostheses would greatly enhance their ability to interact with the environment. This thesis investigates the possibility to rebuild a human fingertip with its mechanical sensing capabilities. A soft, human-sized artificial fingertip was developed, equipped with an array of 144 tactile sensors (taxels). These 0.5 mm diameter taxels can detect touch, vibrations, and shear, enabling the artificial finger to distinguish between different external stimuli. This thesis describes the design of the taxels, the fabrication as well as the characterization. The taxels can sense pressures with a sensitivity of 2.6 kPa-1 and were tested in a temperature range of 20 - 80° C as well as over 10000 cycles. The sensing characteristics are determined by the thickness of a spray-coated silicone layer that encases the sensors, increasing their robustness to external influences. The static and dynamic sensing capabilities of the encapsulated taxels were evaluated. The sensitivity can be modifed according to the needs of an application. Skin thicknesses between 0 - 660µm allowed sensitivities of 0.86 - 0.035 kPa-1. A similar trend was observed for dynamic sensing capabilities. The softness of a human finger was measured to create an artificial finger of similar conformity. Simulation results supported the transfer of taxel characteristics from on-chip to the soft fingertip. Miniaturized readout electronics allowed to read the full finger at 220 Hz, enabling the observation of touch and slipping events on the artificial finger and the estimation of the contact force. Slipping events can be detected as vibrations registered by individual sensors, while the contact force can be estimated by averaging sensor array readouts. The robustness of the fingers was tested by applying 15 N for >2000 times, which resulted in only minor degradation in stiffened membranes. Neural networks were tested to extract simple features like object recognit