Along with the industry technology incessant progress, the demand for electronic products in the family and offices is extremely increased especially for the short range application products. However it appears that in the utilization of these wired electronic products it generates the problem of not easy to maintain a safe and clean environment. It is imperative and a trend that these wired electronic products will be replaced by their wireless counterparts and consequently it becomes indispensable that it needs to develop the technology for short range wireless transmission. The commonly used technology in the low power and short range transmission environment is the infrared system, and the most application of the infrared technology is the use of remote controller in the daily life. But it has many inherent shortcomings in the infrared technology, for example, its transmitting range is short, its transmission direction is confined, it needs to have a clear path in its transmission and it can have only two devices interconnected simultaneously. In this thesis we propose a transceiver system that is implemented by using the Gaussian Frequency Shift Keying method. It has the advantages that it has not only the merits of the infrared technology but it also has longer transmission range than that of the infrared system, it has no confining direction in its transmission and it can have more than two devices interconnected simultaneously. Because of the afore-mentioned advantages the wireless electronic products have become more pleasing and convenience to use and have been found more application areas. In this thesis we propose the design of a GFSK modulation system based on the Top-Down design concept. We use Verilog hardware description (HDL) language to design a GFSK modulation system with intermediate frequency set at 1 MHz. This designed system is implemented on the FPGA application platform. The information data is generated through the implementation of a pseudo noise generator, the data is passing through scrambler, manchester encoder, convolutional encoder, Interleaver and passed through a Gaussian filter before they enter into the modulator. The Gaussian filter will smooth the data stream to avoid the possibility of generating out-of-band spectrum before it enters the modulator, and due to this spectrum smoothing characteristic it will reduce the interference effect from the neighboring channels. The modulated signal is then transmitted through the white noise affected channel and limiting amplifier or RF module to the receiver end. At the receiver the received signal is passing through the, demodulator, infinite impulse response (IIR) filter, deinterleaver, Viterbi decoder and the descrambler to regenerate the transmitted data. The system bit error rate (BER) is measured and analyzed. The system performance can be improved by implementing error correcting block in the system.