Thermo-mechanical processing, such as hot-rolling or forging, are established processes to improve mechanical properties and to homogenize the microstructure of titanium and its alloys. However, thermo-mechanical processing can generate crystallographic texture. The crystallographic texture evolution due to these processing has been larger reported in the literature, this is not the case for titanium alloys subjected to uniaxial compression. The α and β-texture evolution during uniaxial compression in the dual phase titanium alloys is not well understood. In this project, we aim to enhance our understanding of texture evolution and predictions by studying Ti-64 subjected to uniaxial compression in beta phase. The project involves high throughput texture measurement in titanium alloys and understanding of the microstructure and texture evolution during hot forming of the alloys. The electron back-scatter diffraction (EBSD) will be used to measure the texture and micro-texture in the hot formed materials, across large data sets and industrial scale components. The EBSD data will be reconstructed using MTEX to obtain beta texture and beta sub-grain size determined as a function of strain rate during beta processing. The goal is to use the results to establish physically based model to predict the texture evolution under compression. This physically based model will be beneficial to the aerospace industries.