Low-profile antennas are required for aircraft, satellites, radar, and a variety of other vehicles due to aerodynamic considerations. The "patch" or microstrip antenna is a narrow band antenna with a low profile and low gain. Patch antennas are becoming more popular as a result of their ability to be printed on a circuit board. Microstrip antennas can be rectangular, circular, elliptical, or any other regular form, but the most common configurations are rectangular and circular. This research constructed a rectangular patch antenna that operates in the 3.3 GHz (S-band) operating frequency based on a description of microstrip antenna working principles. Agilent ADS Momentum software is used to create and simulate the antenna model. Finally, by optimizing and matching to meets, the best performance parameters such as Gain, Directivity, Efficiency, Power Intensity, Radiated power, and Return loss are obtained.

Researches in the reduction of peak-to-average power ratio (PAPR) from orthogonal frequency division multiplexing (OFDM) output signals are being done using many techniques. Selected mapping (SLM) technique is a distortion-less technique and is a well known method to reduce high PAPR of OFDM signal. One drawback of SLM is its requirement of side information bits to recover original data block at the receiver side which lead rate of data loss. In this paper, we have proposed a sequential phase sequence SLM (SPS-SLM) based OFDM transceiver without side information and studied its performance. For the proposed method, a specific set of phase sequences is designed. MATLAB simulation shows that the proposed scheme performs well in terms of PAPR. Proposed method provides almost the same PAPR reduction performance compared to the conventional SLM method requiring side information.