In the past, the challenge for wireless video transmission was mainly the datarate, which affected the video quality. However, with the advent of ultra-wide band (UWB) radio technologies, wireless network systems started to adopt multiple channels to increase the datarate. While it is possible to achieve satisfactory transmission datarates for high-definition wireless video transmission today, efficiently processing the large quantity of real-time video data and properly managing the multi-channel transmission have surfaced as major challenges in the design of a wireless video systems. In this thesis, we proposed a framework and built a prototype to achieve real-time video transmission. In the proposed framework, hardware components first divide the images that we intend to transmit into many small blocks of data, and then compress and decompress the blocks in parallel before and after wireless transmission, so that the data streams can also be transmitted in parallel through multiple channels to deliver video with higher datarate, better security, and more tolerance to interference. Our prototype employed a standard 802.11 wireless network card into an FPGA platform to implement the aforementioned framework. The results from our experiments showed that the transmission system was capable of delivering video frames even in a unreliable wireless environment, which made it an applicable design in disaster scenes. In addition, the proposed framework is extensible as the number of wireless network cards could be further increased to provide the datarate required by high-denition video transmission.