Interfacial reactions, microstructural evolution and shear strength of infrared brazed Ti50Ni50 and Invar joint using BAg-8, Cusil-ABA, and Ticusil filler foils have been investigated. All Ag-based fillers well wet the Invar substrate, and their wettability can be further improved by minor Ti addition. The brazed joint using BAg-8 is comprised of Ag-Cu eutectic. There is no interfacial reaction layer between BAg-8 braze and Invar substrate. However, Fe2Ti and Ni3Ti intermetallic compounds are observed close to Ti50Ni50 substrate. Average shear strength of Ti50Ni50/ BAg-8/Invar joint brazed at 850 oC for 300 s is 158 MPa. The joint is fractured along the interface close to Ti50Ni50 substrate, and fractograph is featured with cleavage dominated fracture. For Cusil-ABA and Ticusil brazed joints, the sequence of identified phases from Ti50Ni50 to Invar substrate is CuNiTi, Ag-Cu eutectic and mixture of Fe2Ti and Ni3Ti. The specimen brazed at 850 oC for 300 s using Cusil-ABA filler demonstrates the best average shear strength of 249 MPa. The average shear strength of Ti50Ni50/Ticusil/Invar joint brazed at 900 oC for 60 s is 230 MPa. Cracks are initiated from Fe2Ti phase for both Cusil-ABA and Ticusil brazed joints, and their fractographs are dominated by quasi-cleavage fracture. Two modified approaches of infrared brazed Ti50Ni50 and Invar joints using the Cusil-ABA braze are also investigated. For Cu electroplated Invar substrate, the brazed Ti50Ni50/Cusil- ABA/Cu/Invar joint is comprised of CuNiTi, Ag-rich and Cu-rich phases. For the dual filler foils method, the microstructure of brazed Ti50Ni50/Cusil-ABA/BAg-8/Invar joint is similar to that of Ti50Ni50/Cusil-ABA/Invar joint with shear strength of 212 MPa. Based on the experimental observation, the Cusil-ABA foil shows the potential in brazing Ti50Ni50 and Invar substrates.