Optical communication system has been widely used in our daily life. For wireless communications, visible light communication (VLC) has shown its potential as an alternative choice of radio source attribute to the ability of integrating with the exiting lighting infrastructure. With the increasing demand for data content in recent years, improving the component bandwidth has become an important topic. The blue-light light emitting diode luminaries have gradually replaced the traditional light bulbs for solid-state lighting. However, the modulation bandwidth of LEDs is usually limited by the spontaneous carrier lifetime. Therefore, improving the bandwidth of conventional LEDs is the object of this thesis. Generally, there is a trade-off of high-speed performance of the LEDs. By shrinking the mesa size, LEDs can achieve higher bandwidth but sacrifice the light intensity. In this thesis, we used the photonic crystal (PhC) structure embedded in LEDs (PhCLEDs) to improve the performance of the devices and maintain the appropriate light output power. The eye pattern up to 400 Mb/s using on-off keying (OOK) modulation is achieved with a bandwidth of 178 MHz. To further increase the bit rate beyond the bandwidth limit, we also used 16-quadrature amplitude modulation (QAM) orthogonal frequency division multiplexing (OFDM) modulation to transmission data and a data rate up to 2 Gbit/s is obtained with PhCLEDs. The experiments reveal the bandwidth of the LEDs can be improved with photonic crystal structure, and PhCLEDs shown a great potential in visible light communication system. In recent years, the devices with acousto-optic modulation have been widely used. This thesis attempts to enhance the optical properties of VLED by using surface acoustic waves (SAW) generated by interdigital transducers. Since surface acoustic waves at 108 MHz were fed into the VLED, the acoustoelectric current were generated, and the optical output power was also improved about 2.5%. Meanwhile, the piezoelectric vibration was occurred, and the resonance frequencies of different vibration modes are independent with the frequency of SAW. Resonance frequencies comes from different vibration modes would affect each other and achieve frequency up-conversion. Finally, ~GHz optical vibration was achieved and observed. Thus, the 20 MHz RF signal was given and thought of as the carrier which can carry the SAW induced GHz optical oscillation signals. It is an important result to demonstrate a novel A/O modulation for visible light communication applications.