In this study , transformation behaviors and damping capacities of binary and ternary TiNi-based shape memory alloys (SMAs) are investigated. Damping properties of Ti50-xNi50+x (x=0~1.6 at%) and Ti50Ni50-xPdx (x=5~13 at%) SMAs are characterized under temperature and frequency sweep tests by dynamic mechanical analyzer (DMA). According to DMA tested results, solid solution treated binary Ti50-xNi50+x SMAs exhibited B2B19’ one stage transformation have higher magnitude of tan δ value than aged ones exhibited B2R transformation. It is suggested that Ti3Ni4 precipitates might hinder the mobility of R-phase variants‘ interfaces. Besides, relaxation peak appears in R-phase after Ti50-xNi50+x (x>1.0 at%) SMAs have been low-temperature aged. Comparing to other literatures, the activation energy to form the relaxation peak in B19 phase is higher than those in R-phase and B19’ phase. This phenomenon indicates that the abilities of H atoms pinning twin boundaries in B19,B19’ and R-phase are different. For ternary Ti50Ni50-xPdx SMAs, tan δ value magnitude , storage modulus (E0) and strain variation exhibited in B2B19 transformation are all higher than those in B2RB19’ one due to twin boundaries in B19 phase are easier movable and the B2B19 has higher E0 softening and strain variation during transformaiton. For the inherent internal friction under isothermal condition DMA test, it shows the (IFPT+IFI)B2→B19 of Ti50 Ni40Pd10 SMA exhibits higher tanδ value than the other ternary TiNiPd SMAs, and a transformation peak appears at ≈-75℃ in Ti50Ni40Pd10 SMA which has been further confirmed as B19B19’ transformation by the low temperature XRD test.