In this thesis, Sip (System-In-Package) packaging is employed to design a low-cost multi-mode dual-band RF front-end module (FEM), to reach its goal of size-reducing and meet the RF performance requirements, in response to the trends of the current mobile products. For the evolution of the PC interface, from the specification of PCMCIA to Mini PCI, then to PCI-e, its performance does not require any less, though the circuit board area is of strict limit, for which the modular design is an important and consolidation solution. In facts, the multi-channel output and the multi-channel input (MIMO) system architecture of IEEE 802.11n has become the most important factor of occupying a large circuit board area, which can be resolved through the design concept of RF front-end module (FEM). The achieved volume of the front-end RF module implemented in this thesis is about 6x5x1.4mm³. In addition, the working frequency range includes ISM 2GHz/5GHz bands. The module contains RF front-end components and circuitry such as the low noise amplifier, power amplifier, RF switch, RF matching circuits and filters, etc. The Sip packaging process for the RF module, studied is this thesis, can greatly reduce the time and costs for the design and development. Furthermore, the thresholds of its design/development are much smaller than those based on the full integrated circuit type. In this thesis, charts and flow charts are utilized to describe the details of the design of RF front-end module based the Sip packaging process.